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1. Chapter 3 Mass Transfer and Diffusion §3.0 INSTRUCTIONAL OBJECTIVES After

   completing this chapter, you should be able to:  Explain the relationship between mass transfer and phase equilibrium, and why models for both are useful.  Discuss mechanisms of mass transfer, including bulk flow.  State Fick’s law of diffusion for binary mixtures and discuss its analogy to Fourier’s law of heat conduction.  Estimate, in the absence of data, diffusivities for gas, liquid, and solid mixtures.  Calculate multidimensional, unsteady-state molecular diffusion by analogy to heat conduction.  Calculate rates of mass transfer by molecular diffusion in laminar flow for three common cases.  Define a mass-transfer coefficient and explain its analogy to the heat-transfer coefficient.  Use analogies, particularly those of Chilton and Colburn, and Churchill et al., to calculate rates of mass transfer in turbulent flow.  Calculate rates of mass transfer across fluid–fluid interfaces using two-film theory and penetration theory.  Relate molecular motion to potentials arising from chemical, pressure, thermal, gravitational, electrostatic, and friction forces.  Compare the Maxwell–Stefan formulation with Fick’s law for mass transfer.  Use simplified forms of the Maxwell–Stefan relations to characterize mass transport due to chemical, pressure, thermal, centripetal, electrostatic, and friction forces.  Use a linearized form of the Maxwell–Stefan relations to describe film mass transfer in stripping and membrane polarization. Mass transfer is the net movement of a species in a mixture from one location to another. In separation operations, the transfer often takes place across an interface between phases. Absorption by a liquid of a solute from a carrier gas involves transfer of the solute through the gas to the gas–liquid inter- face, across the interface, and into the liquid. Mathematical models for this process—as well as others such as mass trans- fer of a species through a gas to the surface of a porous, ad- sorbent particle—are presented in this book. Two mechanisms of mass transfer are: (1) molecular diffu- sion by random and spontaneous microscopic movement of molecules as a result of thermal motion; and (2) eddy (turbu- lent) diffusion by random, macroscopic fluid motion. Both molecular and eddy diffusion may involve the movement of different species in opposing directions. When a bulk flow occurs, the total rate of mass transfer of individual species is increased or decreased by this bulk flow, which is a third mechanism of mass transfer. Molecular diffusion is extremely slow; eddy diffusion is orders of magnitude more rapid. Therefore, if industrial sepa- ration processes are to be conducted in equipment of reason- able size, the fluids must be agitated and interfacial areas maximized. For solids, the particle size is decreased to in- crease the area for mass transfer and decrease the distance for diffusion. In multiphase systems the extent of the separation is lim- ited by phase equilibrium because, with time, concentrations equilibrate by mass transfer. When mass transfer is rapid, equilibration takes seconds or minutes, and design of separa- tion equipment is based on phase equilibrium, not mass transfer. For separations involving barriers such as mem- branes, mass-transfer rates govern equipment design. Diffusion of species A with respect to B occurs because of driving forces, which include gradients of species concentra- tion (ordinary diffusion), pressure, temperature (thermal dif- fusion), and external force fields that act unequally on different species. Pressure diffusion requires a large gradient, which is achieved for gas mixtures with a centrifuge. Ther- mal diffusion columns can be employed to separate mixtures by establishing a temperature gradient. More widely applied is forced diffusion of ions in an electrical field. This chapter begins by describing only molecular diffu- sion driven by concentration gradients, which is the most common type of diffusion in chemical separation processes. 85

2. Emphasis is on binary systems, for which molecular- diffusion theory

   is relatively simple and applications are straightforward. The other types of diffusion are introduced in §3.8 because of their importance in bioseparations. Multi- component ordinary diffusion is considered briefly in Chap- ter 12. It is a more appropriate topic for advanced study using texts such as Taylor and Krishna [1]. Molecular diffusion occurs in fluids that are stagnant, or in laminar or turbulent motion. Eddy diffusion occurs in fluids when turbulent motion exists. When both molecular diffusion and eddy diffusion occur, they are additive. When mass trans- fer occurs under bulk turbulent flow but across an interface or to a solid surface, flow is generally laminar or stagnant near the interface or solid surface. Thus, the eddy-diffusion mech- anism is dampened or eliminated as the interface or solid sur- face is approached. Mass transfer can result in a total net rate of bulk flow or flux in a direction relative to a fixed plane or stationary coor- dinate system. When a net flux occurs, it carries all species present. Thus, the molar flux of a species is the sum of all three mechanisms. If Ni is the molar flux of i with mole frac- tion xi, and N is the total molar flux in moles per unit time per unit area in a direction perpendicular to a stationary plane across which mass transfer occurs, then Ni ¼ molecular diffusion flux of i þ eddy diffusion flux of i þ xi N ð3-1Þ where xi N is the bulk-flow flux. Each term in (3-1) is positive or negative depending on the direction of the flux relative to the direction selected as positive. When the molecular and eddy-diffusion fluxes are in one direction and N is in the opposite direction (even though a gradient of i exists), the net species mass-transfer flux, Ni, can be zero. This chapter covers eight areas: (1) steady-state diffusion in stagnant media, (2) estimation of diffusion coefficients, (3) unsteady-state diffusion in stagnant media, (4) mass transfer in laminar flow, (5) mass transfer in turbulent flow, (6) mass transfer at fluid–fluid interfaces, (7) mass transfer across fluid–fluid interfaces, and (8) molecular mass transfer in terms of different driving forces in bioseparations. §3.1 STEADY-STATE, ORDINARY MOLECULAR DIFFUSION Imagine a cylindrical glass vessel partly filled with dyed water. Clear water is carefully added on top so that the dyed solution on the bottom is undisturbed. At first, a sharp boundary exists between layers, but as mass transfer of the dye occurs, the upper layer becomes colored and the layer below less colored. The upper layer is more colored near the original interface and less colored in the region near the top. During this color change, the motion of each dye molecule is random, under- going collisions with water molecules and sometimes with dye molecules, moving first in one direction and then in another, with no one direction preferred. This type of motion is some- times called a random-walk process, which yields a mean- square distance of travel in a time interval but not in a direction interval. At a given horizontal plane through the solution, it is not possible to determine whether, in a given time interval, a molecule will cross the plane or not. On the average, a fraction of all molecules in the solution below the plane cross over into the region above and the same fraction will cross over in the opposite direction. Therefore, if the concentration of dye in the lower region is greater than that in the upper region, a net rate of mass transfer of dye takes place from the lower to the upper region. Ultimately, a dynamic equilibrium is achieved and the dye concentration will be uniform throughout. Based on these observations, it is clear that: 1. Mass transfer by ordinary molecular diffusion in a binary mixture occurs because of a concentration gradient; that is, a species diffuses in the direction of decreasing concentration. 2. The mass-transfer rate is proportional to the area nor- mal to the direction of mass transfer. Thus, the rate can be expressed as a flux. 3. Net transfer stops when concentrations are uniform. §3.1.1 Fick’s Law of Diffusion The three observations above were quantified by Fick in 1855. He proposed an analogy to Fourier’s 1822 first law of heat conduction, qz ¼ Àk dT dz ð3-2Þ where qz is the heat flux by conduction in the z-direction, k is the thermal conductivity, and dT=dz is the temperature gradi- ent, which is negative in the direction of heat conduction. Fick’s first law also features a proportionality between a flux and a gradient. For a mixture of A and B, JAz ¼ ÀDAB dcA dz ð3-3aÞ and JBz ¼ ÀDBA dcB dz ð3-3bÞ where JAz is the molar flux of A by ordinary molecular diffu- sion relative to the molar-average velocity of the mixture in the z-direction, DAB is the mutual diffusion coefficient or diffusivity of A in B, cA is the molar concentration of A, and dcA =dz the concentration gradient of A, which is negative in the direction of diffusion. Similar definitions apply to (3-3b). The fluxes of A and B are in opposite directions. If the medium through which diffusion occurs is isotropic, then values of k and DAB are inde- pendent of direction. Nonisotropic (anisotropic) materials inc- lude fibrous and composite solids as well as noncubic crystals. Alternative driving forces and concentrations can be used in (3-3a) and (3-3b). An example is JA ¼ ÀcDAB dxA dz ð3-4Þ where the z subscript on J has been dropped, c ¼ total molar concentration, and xA ¼ mole fraction of A. 86 Chapter 3 Mass Transfer and Diffusion

3. Equation (3-4) can also be written in an equivalent mass

   form, where jA is the mass flux of A relative to the mass- average velocity of the mixture in the positive z-direction, r is the mass density, and wA is the mass fraction of A: j A ¼ ÀrDAB dwA dz ð3-5Þ §3.1.2 Species Velocities in Diffusion If velocities are based on the molar flux, N, and the molar dif- fusion flux, J, then the molar average mixture velocity, yM, relative to stationary coordinates for the binary mixture, is yM ¼ N c ¼ NA þ NB c ð3-6Þ Similarly, the velocity of species i in terms of Ni, relative to stationary coordinates, is: yi ¼ Ni ci ð3-7Þ Combining (3-6) and (3-7) with xi ¼ ci =c gives yM ¼ xA yA þ xB yB ð3-8Þ Diffusion velocities, yiD , defined in terms of Ji, are relative to molar-average velocity and are defined as the difference between the species velocity and the molar-average mixture velocity: yiD ¼ Ji ci ¼ yi À yM ð3-9Þ When solving mass-transfer problems involving net mix- ture movement (bulk flow), fluxes and flow rates based on yM as the frame of reference are inconvenient to use. It is thus preferred to use mass-transfer fluxes referred to stationary coordinates. Thus, from (3-9), the total species velocity is yi ¼ yM þ yiD ð3-10Þ Combining (3-7) and (3-10), Ni ¼ ci yM þ ci yiD ð3-11Þ Combining (3-11) with (3-4), (3-6), and (3-7), NA ¼ nA A ¼ xA N À cDAB dxA dz   ð3-12Þ and NB ¼ nB A ¼ xB N À cDBA dxB dz   ð3-13Þ In (3-12) and (3-13), ni is the molar flow rate in moles per unit time, A is the mass-transfer area, the first right-hand side terms are the fluxes resulting from bulk flow, and the second terms are the diffusion fluxes. Two cases are important: (1) equimolar counterdiffusion (EMD); and (2) unimolecular diffusion (UMD). §3.1.3 Equimolar Counterdiffusion (EMD) In EMD, the molar fluxes in (3-12) and (3-13) are equal but opposite in direction, so N ¼ NA þ NB ¼ 0 ð3-14Þ Thus, from (3-12) and (3-13), the diffusion fluxes are also equal but opposite in direction: JA ¼ ÀJB ð3-15Þ This idealization is approached in distillation of binary mix- tures, as discussed in Chapter 7. From (3-12) and (3-13), in the absence of bulk flow, NA ¼ JA ¼ ÀcDAB dxA dz   ð3-16Þ and NB ¼ JB ¼ ÀcDBA dxB dz   ð3-17Þ If the total concentration, pressure, and temperature are constant and the mole fractions are constant (but different) at two sides of a stagnant film between z1 and z2 , then (3-16) and (3-17) can be integrated from z1 to any z between z1 and z2 to give JA ¼ cDAB z À z1 ðxA1 À xA Þ ð3-18Þ and JB ¼ cDBA z À z1 ðxB1 À xB Þ ð3-19Þ At steady state, the mole fractions are linear in distance, as shown in Figure 3.1a. Furthermore, because total Mole fraction, x Distance, z (a) z1 z2 xA xB Mole fraction, x Distance, z (b) z1 z2 xA xB Figure 3.1 Concentration profiles for limiting cases of ordinary molecular diffusion in binary mixtures across a stagnant film: (a) equimolar counterdiffusion (EMD); (b) unimolecular diffusion (UMD). §3.1 Steady-State, Ordinary Molecular Diffusion 87

4. concentration c is constant through the film, where c ¼

   cA þ cB ð3-20Þ by differentiation, dc ¼ 0 ¼ dcA þ dcB ð3-21Þ Thus, dcA ¼ ÀdcB ð3-22Þ From (3-3a), (3-3b), (3-15), and (3-22), DAB dz ¼ DBA dz ð3-23Þ Therefore, DAB ¼ DBA . This equality of diffusion coeffi- cients is always true in a binary system. EXAMPLE 3.1 EMD in a Tube. Two bulbs are connected by a straight tube, 0.001 m in diameter and 0.15 m in length. Initially the bulb at End 1 contains N2 and the bulb at End 2 contains H2 . Pressure and temperature are constant at 25C and 1 atm. At a time after diffusion starts, the nitrogen content of the gas at End 1 of the tube is 80 mol% and at End 2 is 25 mol%. If the binary diffusion coefficient is 0.784 cm2/s, determine: (a) The rates and directions of mass transfer in mol/s (b) The species velocities relative to stationary coordinates, in cm/s Solution (a) Because the gas system is closed and at constant pressure and temperature, no bulk flow occurs and mass transfer in the con- necting tube is EMD. The area for mass transfer through the tube, in cm2, is A ¼ 3.14(0.1)2=4 ¼ 7.85  10À3 cm2. By the ideal gas law, the total gas concentration (molar density) is c ¼ P PT ¼ 1 ð82:06Þð298Þ ¼ 4.09  10À5 mol/cm3. Take as the reference plane End 1 of the connecting tube. Applying (3-18) to N2 over the tube length, nN2 ¼ cDN2 ;H2 z2 À z1 ðxN2 Þ 1 À ðxN2 Þ 2  à A ¼ ð4:09  10À5Þð0:784Þð0:80 À 0:25Þ 15 ð7:85  10À3Þ ¼ 9:23  10À9 mol/s in the positive z-direction nH2 ¼ 9:23  10À9 mol/s in the negative z-direction (b) For EMD, the molar-average velocity of the mixture, yM, is 0. Therefore, from (3-9), species velocities are equal to species diffusion velocities. Thus, yN2 ¼ ðyN2 Þ D ¼ JN2 cN2 ¼ nN2 AcxN2 ¼ 9:23  10À9 ½ð7:85  10À3Þð4:09  10À5ÞxN2 Š ¼ 0:0287 xN2 in the positive z-direction Similarly, yH2 ¼ 0:0287 xH2 in the negative z-direction Thus, species velocities depend on mole fractions, as follows: z, cm xN2 xH2 yN2 ;cm/s yH2 ;cm/s 0 (End 1) 0.800 0.200 0.0351 À0.1435 5 0.617 0.383 0.0465 À0.0749 10 0.433 0.567 0.0663 À0.0506 15 (End 2) 0.250 0.750 0.1148 À0.0383 Note that species velocities vary along the length of the tube, but at any location z, yM ¼ 0. For example, at z ¼ 10 cm, from (3-8), yM ¼ ð0:433Þð0:0663Þ þ ð0:567ÞðÀ0:0506Þ ¼ 0 §3.1.4 Unimolecular Diffusion (UMD) In UMD, mass transfer of component A occurs through stag- nant B, resulting in a bulk flow. Thus, NB ¼ 0 ð3-24Þ and N ¼ NA ð3-25Þ Therefore, from (3-12), NA ¼ xA NA À cDAB dxA dz ð3-26Þ which can be rearranged to a Fick’s-law form by solving for NA , NA ¼ À cDAB ð1 À xA Þ dxA dz ¼ À cDAB xB dxA dz ð3-27Þ The factor (1 À xA ) accounts for the bulk-flow effect. For a mixture dilute in A, this effect is small. But in an equimolar mixture of A and B, (1 À xA ) ¼ 0.5 and, because of bulk flow, the molar mass-transfer flux of A is twice the ordinary molecular-diffusion flux. For the stagnant component, B, (3-13) becomes 0 ¼ xB NA À cDBA dxB dz ð3-28Þ or xB NA ¼ cDBA dxB dz ð3-29Þ Thus, the bulk-flow flux of B is equal to but opposite its dif- fusion flux. At quasi-steady-state conditions (i.e., no accumulation of species with time) and with constant molar density, (3-27) in integral form is: Z z z1 dz ¼ À cDAB NA Z xA xA1 dxA 1 À xA ð3-30Þ which upon integration yields NA ¼ cDAB z À z1 ln 1 À xA 1 À xA1   ð3-31Þ Thus, the mole-fraction variation as a function of z is xA ¼ 1 À ð1 À xA1 Þexp NA ðz À z1 Þ cDAB ! ð3-32Þ 88 Chapter 3 Mass Transfer and Diffusion

5. Figure 3.1b shows that the mole fractions are thus nonlinear

   in z. A more useful form of (3-31) can be derived from the defi- nition of the log mean. When z ¼ z2 , (3-31) becomes NA ¼ cDAB z2 À z1 ln 1 À xA2 1 À xA1   ð3-33Þ The log mean (LM) of (1 À xA ) at the two ends of the stag- nant layer is ð1 À xA Þ LM ¼ ð1 À xA2 Þ À ð1 À xA1 Þ ln½ð1 À xA2 Þ=ð1 À xA1 ފ ¼ xA1 À xA2 ln½ð1 À xA2 Þ=ð1 À xA1 ފ ð3-34Þ Combining (3-33) with (3-34) gives NA ¼ cDAB z2 À z1 ðxA1 À xA2 Þ ð1 À xA Þ LM ¼ cDAB ð1 À xA Þ LM ðÀDxA Þ Dz ¼ cDAB ðxB Þ LM ðÀDxA Þ Dz ð3:35Þ EXAMPLE 3.2 Evaporation from an Open Beaker. In Figure 3.2, an open beaker, 6 cm high, is filled with liquid ben- zene (A) at 25C to within 0.5 cm of the top. Dry air (B) at 25C and 1 atm is blown across the mouth of the beaker so that evaporated benzene is carried away by convection after it transfers through a stagnant air layer in the beaker. The vapor pressure of benzene at 25C is 0.131 atm. Thus, as shown in Figure 3.2, the mole fraction of benzene in the air at the top of the beaker is zero and is deter- mined by Raoult’s law at the gas–liquid interface. The diffusion coefficient for benzene in air at 25C and 1 atm is 0.0905 cm2/s. Compute the: (a) initial rate of evaporation of benzene as a molar flux in mol/cm2-s; (b) initial mole-fraction profiles in the stagnant air layer; (c) initial fractions of the mass-transfer fluxes due to molecular diffusion; (d) initial diffusion velocities, and the species velocities (relative to stationary coordinates) in the stagnant layer; (e) time for the benzene level in the beaker to drop 2 cm if the spe- cific gravity of benzene is 0.874. Neglect the accumulation of benzene and air in the stagnant layer with time as it increases in height (quasi-steady-state assumption). Solution The total vapor concentration by the ideal-gas law is: c ¼ P RT ¼ 1 ð82:06Þð298Þ ¼ 4:09  10À5 mol/cm3 (a) With z equal to the distance down from the top of the beaker, let z1 ¼ 0 at the top of beaker and z2 ¼ the distance from the top of the beaker to gas–liquid interface. Then, initially, the stagnant gas layer is z2 À z1 ¼ Dz ¼ 0.5 cm. From Dalton’s law, assum- ing equilibrium at the liquid benzene–air interface, xA1 ¼ p A1 P ¼ 0:131 1 ¼ 0:131; xA2 ¼ 0 ð1 À xA Þ LM ¼ 0:131 ln½ð1 À 0Þ=ð1 À 0:131ފ ¼ 0:933 ¼ ðxB Þ LM From (3-35), NA ¼ ð4:09  10À6Þð0:0905Þ 0:5 0:131 0:933   ¼ 1:04  10À6 mol/cm2-s (b) NA ðz À z1 Þ cDAB ¼ ð1:04  10À6Þðz À 0Þ ð4:09  10À5Þð0:0905Þ ¼ 0:281 z From (3-32), xA ¼ 1 À 0:869 exp ð0:281 zÞ ð1Þ Using (1), the following results are obtained: z, cm xA xB 0.0 0.1310 0.8690 0.1 0.1060 0.8940 0.2 0.0808 0.9192 0.3 0.0546 0.9454 0.4 0.0276 0.9724 0.5 0.0000 1.0000 These profiles are only slightly curved. (c) Equations (3-27) and (3-29) yield the bulk-flow terms, xA NA and xB NA , from which the molecular-diffusion terms are obtained. xi N Bulk-Flow Flux, mol/cm2-s  106 Ji Molecular-Diffusion Flux, mol/cm2-s  106 z, cm A B A B 0.0 0.1360 0.9040 0.9040 À0.9040 0.1 0.1100 0.9300 0.9300 À0.9300 0.2 0.0840 0.9560 0.9560 À0.9560 0.3 0.0568 0.9832 0.9832 À0.9832 0.4 0.0287 1.0113 1.0113 À1.0113 0.5 0.0000 1.0400 1.0400 À1.0400 Note that the molecular-diffusion fluxes are equal but opposite and that the bulk-flow flux of B is equal but opposite to its molec- ular diffusion flux; thus NB is zero, making B (air) stagnant. Mass transfer Air 1 atm 25°C xA = 0 z xA = PA s /P Liquid Benzene Interface Beaker 0.5 cm 6 cm Figure 3.2 Evaporation of benzene from a beaker—Example 3.2. §3.1 Steady-State, Ordinary Molecular Diffusion 89

6. (d) From (3-6), yM ¼ N c ¼ NA c

   ¼ 1:04  10À6 4:09  10À5 ¼ 0:0254 cm/s ð2Þ From (3-9), the diffusion velocities are given by yid ¼ Ji ci ¼ Ji xi c ð3Þ From (3-10), species velocities relative to stationary coordinates are yi ¼ yid þ yM ð4Þ Using (2) to (4), there follows yid Ji Molecular-Diffusion Velocity, cm/s Species Velocity, cm/s z, cm A B A B 0.0 0.1687 À0.0254 0.1941 0 0.1 0.2145 À0.0254 0.2171 0 0.2 0.2893 À0.0254 0.3147 0 0.3 0.4403 À0.0254 0.4657 0 0.4 0.8959 À0.0254 0.9213 0 0.5 1 À0.0254 1 0 Note that yA is zero everywhere, because its molecular- diffusion velocity is negated by the molar-mean velocity. (e) The mass-transfer flux for benzene evaporation equals the rate of decrease in the moles of liquid benzene per unit cross section area of the beaker. Using (3-35) with Dz ¼ z, NA ¼ cDAB z ðÀDxA Þ ð1 À xA Þ LM ¼ rL ML dz dt ð5Þ Separating variables and integrating, Z t 0 dt ¼ t ¼ rL ð1 À xA Þ LM ML cDAB ðÀDxA Þ Z z2 z1 z dz ð6Þ where now z1 ¼ initial location of the interface and z2 ¼ location of the interface after it drops 2 cm. The coefficient of the integral on the RHS of (6) is constant at 0:874ð0:933Þ 78:11ð4:09  10À5Þð0:0905Þð0:131Þ ¼ 21;530 s/cm2 Z z2 z1 z dz ¼ Z 2:5 0:5 z dz ¼ 3 cm2 From (6), t ¼ 21,530(3) ¼ 64,590 s or 17.94 h, which is a long time because of the absence of turbulence. §3.2 DIFFUSION COEFFICIENTS (DIFFUSIVITIES) Diffusion coefficients (diffusivities) are defined for a binary mixture by (3-3) to (3-5). Measurement of diffusion coeffi- cients involve a correction for bulk flow using (3-12) and (3-13), with the reference plane being such that there is no net molar bulk flow. The binary diffusivities, DAB and DBA , are called mutual or binary diffusion coefficients. Other coefficients include DiM , the diffusivity of i in a multicomponent mixture; Dii, the self-diffusion coefficient; and the tracer or interdiffusion coefficient. In this chapter and throughout this book, the focus is on the mutual diffusion coefficient, which will be referred to as the diffusivity or diffusion coefficient. §3.2.1 Diffusivity in Gas Mixtures As discussed by Poling, Prausnitz, and O’Connell [2], equa- tions are available for estimating the value of DAB ¼ DBA in gases at low to moderate pressures. The theoretical equations based on Boltzmann’s kinetic theory of gases, the theorem of corresponding states, and a suitable intermolecular energy- potential function, as developed by Chapman and Enskog, predict DAB to be inversely proportional to pressure, to increase significantly with temperature, and to be almost independent of composition. Of greater accuracy and ease of use is the empiri- cal equation of Fuller, Schettler, and Giddings [3], which retains the form of the Chapman–Enskog theory but utilizes empirical constants derived from experimental data: DAB ¼ DBA ¼ 0:00143T1:75 P M1=2 AB ½ð P V Þ1=3 A þ ð P V Þ1=3 B Š2 ð3-36Þ where DAB is in cm2/s, P is in atm, T is in K, MAB ¼ 2 ð1=MA Þ þ ð1=MB Þ ð3-37Þ and P V ¼ summation of atomic and structural diffusion vol- umes from Table 3.1, which includes diffusion volumes of sim- ple molecules. Table 3.1 Diffusion Volumes from Fuller, Ensley, and Giddings [J. Phys. Chem.,73, 3679–3685 (1969)] for Estimating Binary Gas Diffusivities by the Method of Fuller et al. [3] Atomic Diffusion Volumes and Structural Diffusion-Volume Increments C 15.9 F 14.7 H 2.31 Cl 21.0 O 6.11 Br 21.9 N 4.54 I 29.8 Aromatic ring À18.3 S 22.9 Heterocyclic ring À18.3 Diffusion Volumes of Simple Molecules He 2.67 CO 18.0 Ne 5.98 CO2 26.7 Ar 16.2 N2 O 35.9 Kr 24.5 NH3 20.7 Xe 32.7 H2 O 13.1 H2 6.12 SF6 71.3 D2 6.84 Cl2 38.4 N2 18.5 Br2 69.0 O2 16.3 SO2 41.8 Air 19.7 90 Chapter 3 Mass Transfer and Diffusion

7. Experimental values of binary gas diffusivity at 1 atm and

   near-ambient temperature range from about 0.10 to 10.0 cm2/s. Poling et al. [2] compared (3-36) to experimental data for 51 different binary gas mixtures at low pressures over a tem- perature range of 195–1,068 K. The average deviation was only 5.4%, with a maximum deviation of 25%. Equation (3-36) indicates that DAB is proportional to T1.75=P, which can be used to adjust diffusivities for T and P. Representative experimental values of binary gas diffusivity are given in Table 3.2. EXAMPLE 3.3 Estimation of a Gas Diffusivity. Estimate the diffusion coefficient for oxygen (A)/benzene (B) at 38C and 2 atm using the method of Fuller et al. Solution From (3-37), MAB ¼ 2 ð1=32Þ þ ð1=78:11Þ ¼ 45:4 From Table 3.1, ð P V ÞA ¼ 16.3 and ð P V ÞB ¼ 6(15.9) þ 6(2.31) – 18.3 ¼ 90.96 From (3-36), at 2 atm and 311.2 K, DAB ¼ DBA ¼ 0:00143ð311:2Þ1:75 ð2Þð45:4Þ1=2½16:31=3 þ 90:961=3Š2 ¼ 0:0495 cm2/s At 1 atm, the predicted diffusivity is 0.0990 cm2/s, which is about 2% below the value in Table 3.2. The value for 38C can be corrected for temperature using (3-36) to give, at 200C: DAB at 200C and 1 atm ¼ 0:102 200 þ 273:2 38 þ 273:2   1:75 ¼ 0:212 cm2/s For light gases, at pressures to about 10 atm, the pressure dependence on diffusivity is adequately predicted by the inverse relation in (3-36); that is, PDAB ¼ a constant. At higher pressures, deviations are similar to the modification of the ideal-gas law by the compressibility factor based on the theo- rem of corresponding states. Takahashi [4] published a corre- sponding-states correlation, shown in Figure 3.3, patterned after a correlation by Slattery [5]. In the Takahashi plot, DAB P=(DAB P)LP is a function of reduced temperature and pres- sure, where (DAB P)LP is at low pressure when (3-36) applies. Mixture critical temperature and pressure are molar-average values. Thus, a finite effect of composition is predicted at high pressure. The effect of high pressure on diffusivity is important in supercritical extraction, discussed in Chapter 11. EXAMPLE 3.4 Estimation of a Gas Diffusivity at High Pressure. Estimate the diffusion coefficient for a 25/75 molar mixture of argon and xenon at 200 atm and 378 K. At this temperature and 1 atm, the diffusion coefficient is 0.180 cm2/s. Critical constants are: Tc, K Pc, atm Argon 151.0 48.0 Xenon 289.8 58.0 Table 3.2 Experimental Binary Diffusivities of Gas Pairs at 1 atm Gas pair, A-B Temperature, K DAB , cm2/s Air—carbon dioxide 317.2 0.177 Air—ethanol 313 0.145 Air—helium 317.2 0.765 Air—n-hexane 328 0.093 Air—water 313 0.288 Argon—ammonia 333 0.253 Argon—hydrogen 242.2 0.562 Argon—hydrogen 806 4.86 Argon—methane 298 0.202 Carbon dioxide—nitrogen 298 0.167 Carbon dioxide—oxygen 293.2 0.153 Carbon dioxide—water 307.2 0.198 Carbon monoxide—nitrogen 373 0.318 Helium—benzene 423 0.610 Helium—methane 298 0.675 Helium—methanol 423 1.032 Helium—water 307.1 0.902 Hydrogen—ammonia 298 0.783 Hydrogen—ammonia 533 2.149 Hydrogen—cyclohexane 288.6 0.319 Hydrogen—methane 288 0.694 Hydrogen—nitrogen 298 0.784 Nitrogen—benzene 311.3 0.102 Nitrogen—cyclohexane 288.6 0.0731 Nitrogen—sulfur dioxide 263 0.104 Nitrogen—water 352.1 0.256 Oxygen—benzene 311.3 0.101 Oxygen—carbon tetrachloride 296 0.0749 Oxygen—cyclohexane 288.6 0.0746 Oxygen—water 352.3 0.352 From Marrero, T. R., and E. A. Mason, J. Phys. Chem. Ref. Data, 1, 3–118 (1972). DAB P/(DAB P)LP 1.0 0.8 0.6 0.4 0.2 0.0 1.0 0.9 1.0 1.1 1.2 1.3 1.4 1.5 1.6 1.8 2.0 2.5 3.0 3.5 2.0 3.0 Reduced Pressure, Pr Tr 4.0 5.0 6.0 Figure 3.3 Takahashi [4] correlation for effect of high pressure on binary gas diffusivity. §3.2 Diffusion Coefficients (Diffusivities) 91

8. Solution Calculate reduced conditions: Tc ¼ 0.25(151) þ 0.75(289.8) ¼

   255.1 K Tr ¼ T=Tc ¼ 378=255.1 ¼ 1.48 Pc ¼ 0.25(48) þ 0.75(58) ¼ 55.5 Pr ¼ P=Pc ¼ 200=55.5 ¼ 3.6 From Figure 3.3, DAB P ðDAB PÞ LP ¼ 0:82 DAB ¼ ðDAB PÞ LP P DAB P ðDAB PÞ LP ! ¼ ð0:180Þð1Þ 200 ð0:82Þ ¼ 7:38 Â 10À4cm/s §3.2.2 Diffusivity in Nonelectrolyte Liquid Mixtures For liquids, diffusivities are difficult to estimate because of the lack of a rigorous model for the liquid state. An exception is a dilute solute (A) of large, rigid, spherical molecules dif- fusing through a solvent (B) of small molecules with no slip at the surface of the solute molecules. The resulting relation, based on the hydrodynamics of creeping flow to describe drag, is the Stokes–Einstein equation: ðDAB Þ 1 ¼ RT 6pmB RA NA ð3-38Þ where RA is the solute-molecule radius and NA is Avogadro’s number. Equation (3-38) has long served as a starting point for more widely applicable empirical correlations for liquid diffusivity. Unfortunately, unlike for gas mixtures, where DAB ¼ DBA , in liquid mixtures diffusivities can vary with composition, as shown in Example 3.7. The Stokes–Einstein equation is restricted to dilute binary mixtures of not more than 10% solutes. An extension of (3-38) to more concentrated solutions for small solute molecules is the empirical Wilke–Chang [6] equation: ðDAB Þ 1 ¼ 7:4 Â 10À8ðfB MB Þ1=2T mB y0:6 A ð3-39Þ where the units are cm2/s for DAB ; cP (centipoises) for the solvent viscosity, mB ; K for T; and cm3/mol for yA , the solute molar volume, at its normal boiling point. The parameter fB is a solvent association factor, which is 2.6 for water, 1.9 for methanol, 1.5 for ethanol, and 1.0 for unassociated solvents such as hydrocarbons. The effects of temperature and viscos- ity in (3-39) are taken identical to the prediction of the Stokes–Einstein equation, while the radius of the solute molecule is replaced by yA, which can be estimated by sum- ming atomic contributions tabulated in Table 3.3. Some Table 3.3 Molecular Volumes of Dissolved Light Gases and Atomic Contributions for Other Molecules at the Normal Boiling Point Atomic Volume (m3/kmol) Â 103 Atomic Volume (m3/kmol) Â 103 C 14.8 Ring H 3.7 Three-membered, as in À6 O (except as below) 7.4 ethylene oxide Doubly bonded as carbonyl 7.4 Four-membered À8.5 Coupled to two other elements: Five-membered À11.5 In aldehydes, ketones 7.4 Six-membered À15 In methyl esters 9.1 Naphthalene ring À30 In methyl ethers 9.9 Anthracene ring À47.5 In ethyl esters 9.9 Molecular Volume (m3/kmol) Â 103 In ethyl ethers 9.9 In higher esters 11.0 In higher ethers 11.0 Air 29.9 In acids (—OH) 12.0 O2 25.6 Joined to S, P, N 8.3 N2 31.2 N Br2 53.2 Doubly bonded 15.6 Cl2 48.4 In primary amines 10.5 CO 30.7 In secondary amines 12.0 CO2 34.0 Br 27.0 H2 14.3 Cl in RCHClR0 24.6 H2 O 18.8 Cl in RCl (terminal) 21.6 H2 S 32.9 F 8.7 NH3 25.8 I 37.0 NO 23.6 S 25.6 N2 O 36.4 P 27.0 SO2 44.8 Source: G. Le Bas, The Molecular Volumes of Liquid Chemical Compounds, David McKay, New York (1915). 92 Chapter 3 Mass Transfer and Diffusion

9. representative experimental values of solute diffusivity in dilute binary liquid

   solutions are given in Table 3.4. EXAMPLE 3.5 Estimation of a Liquid Diffusivity. Use the Wilke–Chang equation to estimate the diffusivity of aniline (A) in a 0.5 mol% aqueous solution at 20C. The solubility of aniline in water is 4 g/100 g or 0.77 mol%. Compare the result to the experimental value in Table 3.4. Solution mB ¼ mH2O ¼ 1:01 cP at 20C yA ¼ liquid molar volume of aniline at its normal boiling point of 457.6 K ¼ 107 cm3/mol fB ¼ 2:6 for water; MB ¼ 18 for water; T ¼ 293 K From (3-39), DAB ¼ ð7:4  10À8Þ½2:6ð18ފ0:5ð293Þ 1:01ð107Þ0:6 ¼ 0:89  10À5cm2/s This value is about 3% less than the experimental value of 0.92  10À5 cm2/s for an infinitely dilute solution of aniline in water. More recent liquid diffusivity correlations due to Hayduk and Minhas [7] give better agreement than the Wilke–Chang equation with experimental values for nonaqueous solutions. For a dilute solution of one normal paraffin (C5 to C32 ) in another (C5 to C16 ), ðDAB Þ 1 ¼ 13:3  10À8 T1:47me B y0:71 A ð3-40Þ where e ¼ 10:2 yA À 0:791 ð3-41Þ and the other variables have the same units as in (3-39). For nonaqueous solutions in general, ðDAB Þ 1 ¼ 1:55  10À8 T1:29ðP0:5 B =P0:42 A Þ m0:92 B y0:23 B ð3-42Þ where P is the parachor, which is defined as P ¼ ys1=4 ð3-43Þ When units of liquid molar volume, y, are cm3/mol and surface tension, s, are g/s2 (dynes/cm), then the units of the parachor are cm3-g1/4/s1/2-mol. Normally, at near-ambient conditions, P is treated as a constant, for which a tabulation is given in Table 3.5 from Quayle [8], who also provides in Table 3.6 a group-contribution method for estimating the parachor for compounds not listed. The restrictions that apply to (3-42) are: 1. Solvent viscosity should not exceed 30 cP. 2. For organic acid solutes and solvents other than water, methanol, and butanols, the acid should be treated as a dimer by doubling the values of PA and yA. 3. For a nonpolar solute in monohydroxy alcohols, values of yB and PB should be multiplied by 8 mB , where vis- cosity is in centipoise. Liquid diffusivities range from 10À6 to 10À4 cm2/s for solutes of molecular weight up to about 200 and solvents with viscosity up to 10 cP. Thus, liquid diffusivities are five orders of magnitude smaller than diffusivities for gas mix- tures at 1 atm. However, diffusion rates in liquids are not necessarily five orders of magnitude smaller than in gases because, as seen in (3-5), the product of concentration (molar density) and diffusivity determines the rate of diffu- sion for a given gradient in mole fraction. At 1 atm, the molar density of a liquid is three times that of a gas and, thus, the diffusion rate in liquids is only two orders of magnitude smaller than in gases at 1 atm. EXAMPLE 3.6 Estimation of Solute Liquid Diffusivity. Estimate the diffusivity of formic acid (A) in benzene (B) at 25C and infinite dilution, using the appropriate correlation of Hayduk and Minhas. Solution Equation (3-42) applies, with T ¼ 298 K PA ¼ 93:7 cm3-g1=4=s1=2-mol PB ¼ 205:3 cm3-g1=4/s1=2-mol mB ¼ 0:6 cP at 25C yB ¼ 96 cm3/mol at 80C Table 3.4 Experimental Binary Liquid Diffusivities for Solutes, A, at Low Concentrations in Solvents, B Solvent, B Solute, A Temperature, K Diffusivity, DAB , cm2/s  105 Water Acetic acid 293 1.19 Aniline 293 0.92 Carbon dioxide 298 2.00 Ethanol 288 1.00 Methanol 288 1.26 Ethanol Allyl alcohol 293 0.98 Benzene 298 1.81 Oxygen 303 2.64 Pyridine 293 1.10 Water 298 1.24 Benzene Acetic acid 298 2.09 Cyclohexane 298 2.09 Ethanol 288 2.25 n-heptane 298 2.10 Toluene 298 1.85 n-hexane Carbon tetrachloride 298 3.70 Methyl ethyl ketone 303 3.74 Propane 298 4.87 Toluene 298 4.21 Acetone Acetic acid 288 2.92 Formic acid 298 3.77 Nitrobenzene 293 2.94 Water 298 4.56 From Poling et al. [2]. §3.2 Diffusion Coefficients (Diffusivities) 93

10. However, for formic acid, PA is doubled to 187.4. From

    (3-41), ðDAB Þ 1 ¼ 1:55 Â 10À8 2981:29ð205:30:5=187:40:42Þ 0:60:92960:23 ! ¼ 2:15 Â 10À5cm2/s which is within 6% of the experimental value of 2.28 Â 10À5 cm2/s. The Stokes–Einstein and Wilke–Chang equations predict an inverse dependence of liquid diffusivity with viscosity, while the Hayduk–Minhas equations predict a somewhat smaller depen- dence. The consensus is that liquid diffusivity varies inversely with viscosity raised to an exponent closer to 0.5 than to 1.0. The Stokes–Einstein and Wilke–Chang equations also predict that DAB mB =T is a constant over a narrow temperature range. Because mB decreases exponentially with temperature, DAB is predicted to increase exponentially with temperature. Over a wide temperature range, it is preferable to express the effect of temperature on DAB by an Arrhenius-type expression, ðDAB Þ 1 ¼ A exp ÀE RT   ð3-44Þ where, typically, the activation energy for liquid diffusion, E, is no greater than 6,000 cal/mol. Equations (3-39), (3-40), and (3-42) apply only to solute A in a dilute solution of solvent B. Unlike binary gas mix- tures in which the diffusivity is almost independent of com- position, the effect of composition on liquid diffusivity is complex, sometimes showing strong positive or negative deviations from linearity with mole fraction. Vignes [9] has shown that, except for strongly associated binary mixtures such as chloroform-acetone, which exhibit a rare negative deviation from Raoult’s law, infinite-dilution binary diffusivities, (D)1, can be combined with mixture activity-coefficient data or correlations thereof to predict liquid binary diffusion coefficients over the entire composi- tion range. The Vignes equations are: DAB ¼ ðDAB ÞxB 1 ðDBA ÞxA 1 1 þ q ln gA q ln xA   T;P ð3-45Þ DBA ¼ ðDBA ÞxA 1 ðDAB ÞxB 1 1 þ q ln gB q ln xB   T;P ð3-46Þ EXAMPLE 3.7 Effect of Composition on Liquid Diffusivities. At 298 K and 1 atm, infinite-dilution diffusion coefficients for the methanol (A)–water (B) system are 1.5 Â 10À5 cm2/s and 1.75 Â 10À5 cm2/s for AB and BA, respectively. Table 3.5 Parachors for Representative Compounds Parachor, cm3 -g1/4/s1/2-mol Parachor, cm3-g1/4/s1/2-mol Parachor, cm3 -g1/4/s1/2-mol Acetic acid 131.2 Chlorobenzene 244.5 Methyl amine 95.9 Acetone 161.5 Diphenyl 380.0 Methyl formate 138.6 Acetonitrile 122 Ethane 110.8 Naphthalene 312.5 Acetylene 88.6 Ethylene 99.5 n-octane 350.3 Aniline 234.4 Ethyl butyrate 295.1 1-pentene 218.2 Benzene 205.3 Ethyl ether 211.7 1-pentyne 207.0 Benzonitrile 258 Ethyl mercaptan 162.9 Phenol 221.3 n-butyric acid 209.1 Formic acid 93.7 n-propanol 165.4 Carbon disulfide 143.6 Isobutyl benzene 365.4 Toluene 245.5 Cyclohexane 239.3 Methanol 88.8 Triethyl amine 297.8 Source: Meissner, Chem. Eng. Prog., 45, 149–153 (1949). Table 3.6 Structural Contributions for Estimating the Parachor Carbon–hydrogen: R—[—CO—]—R0 (ketone) C 9.0 R þ R0 ¼ 2 51.3 H 15.5 R þ R0 ¼ 3 49.0 CH3 55.5 R þ R0 ¼ 4 47.5 CH2 in —(CH2 )n R þ R0 ¼ 5 46.3 n < 12 40.0 R þ R0 ¼ 6 45.3 n > 12 40.3 R þ R0 ¼ 7 44.1 —CHO 66 Alkyl groups 1-Methylethyl 133.3 O (not noted above) 20 1-Methylpropyl 171.9 N (not noted above) 17.5 1-Methylbutyl 211.7 S 49.1 2-Methylpropyl 173.3 P 40.5 1-Ethylpropyl 209.5 F 26.1 1,1-Dimethylethyl 170.4 Cl 55.2 1,1-Dimethylpropyl 207.5 Br 68.0 1,2-Dimethylpropyl 207.9 I 90.3 1,1,2-Trimethylpropyl 243.5 Ethylenic bonds: C6 H5 189.6 Terminal 19.1 2,3-position 17.7 Special groups: 3,4-position 16.3 —COO— 63.8 —COOH 73.8 Triple bond 40.6 —OH 29.8 —NH2 42.5 Ring closure: —O— 20.0 Three-membered 12 —NO2 74 Four-membered 6.0 —NO3 (nitrate) 93 Five-membered 3.0 —CO(NH2 ) 91.7 Six-membered 0.8 Source: Quale [8]. 94 Chapter 3 Mass Transfer and Diffusion

11. Activity-coefficient data over a range of compositions as esti- mated

    by UNIFAC are: xA gA xB gB 0.5 1.116 0.5 1.201 0.6 1.066 0.4 1.269 0.7 1.034 0.3 1.343 0.8 1.014 0.2 1.424 1.0 1.000 0.0 1.605 Use the Vignes equations to estimate diffusion coefficients over a range of compositions. Solution Using a spreadsheet to compute the derivatives in (3-45) and (3-46), which are found to be essentially equal at any composition, and the diffusivities from the same equations, the following results are obtained with DAB ¼ DBA at each composition. The calculations show a minimum diffusivity at a methanol mole fraction of 0.30. xA DAB , cm2/s DBA , cm2/s 0.20 1.10  10À5 1.10  10À5 0.30 1.08  10À5 1.08  10À5 0.40 1.12  10À5 1.12  10À5 0.50 1.18  10À5 1.18  10À5 0.60 1.28  10À5 1.28  10À5 0.70 1.38  10À5 1.38  10À5 0.80 1.50  10À5 1.50  10À5 If the diffusivity is assumed to be linear with the mole fraction, the value at xA ¼ 0.50 is 1.625  10À5, which is almost 40% higher than the predicted value of 1.18  10À5. §3.2.3 Diffusivities of Electrolytes For an electrolyte solute, diffusion coefficients of dissolved salts, acids, or bases depend on the ions. However, in the absence of an electric potential, diffusion only of the elec- trolyte is of interest. The infinite-dilution diffusivity in cm2/s of a salt in an aqueous solution can be estimated from the Nernst–Haskell equation: ðDAB Þ 1 ¼ RT½ð1=nþ Þ þ ð1=nÀ ފ F2½ð1=lþ Þ þ ð1=lÀ ފ ð3-47Þ where nþ and nÀ ¼ valences of the cation and anion; lþ and lÀ ¼ limiting ionic conductances in (A/cm2)(V/cm) (g-equiv/cm3), with A in amps and V in volts; F ¼ Faraday’s constant ¼ 96,500 coulombs/g-equiv; T ¼ temperature, K; and R ¼ gas constant ¼ 8.314 J/mol-K. Values of lþ and lÀ at 25C are listed in Table 3.7. At other temperatures, these values are multiplied by T/334 mB , where T and mB are in K and cP, respectively. As the concentration of the electrolyte increases, the diffusivity at first decreases 10% to 20% and then rises to values at a concentration of 2 N (normal) that approximate the infinite- dilution value. Some representative experimental values from Volume V of the International Critical Tables are given in Table 3.8. EXAMPLE 3.8 Diffusivity of an Electrolyte. Estimate the diffusivity of KCl in a dilute solution of water at 18.5C. Compare your result to the experimental value, 1.7  10À5 cm2/s. Table 3.7 Limiting Ionic Conductance in Water at 25C, in (A/cm2)(V/cm)(g-equiv/cm3) Anion lÀ Cation lþ OHÀ 197.6 H+ 349.8 ClÀ 76.3 Li+ 38.7 BrÀ 78.3 Na+ 50.1 IÀ 76.8 K+ 73.5 NOÀ 3 71.4 NHþ 4 73.4 ClOÀ 4 68.0 Ag+ 61.9 HCOÀ 3 44.5 Tl+ 74.7 HCOÀ 2 54.6 ð1 2 ÞMg2þ 53.1 CH3 COÀ 2 40.9 ð1 2 ÞCa2þ 59.5 ClCH2 COÀ 2 39.8 ð1 2 ÞSr2þ 50.5 CNCH2 COÀ 2 41.8 ð1 2 ÞBa2þ 63.6 CH3 CH2 COÀ 2 35.8 ð1 2 ÞCu2þ 54 CH3 ðCH2 Þ 2 COÀ 2 32.6 ð1 2 ÞZn2þ 53 C6 H5 COÀ 2 32.3 ð1 3 ÞLa3þ 69.5 HC2 OÀ 4 40.2 ð1 3 ÞCoðNH3 Þ3þ 6 102 ð1 2 ÞC2 O2À 4 74.2 ð1 2 ÞSO2À 4 80 ð1 3 ÞFeðCNÞ3À 6 101 ð1 4 ÞFeðCNÞ4À 6 111 Source: Poling, Prausnitz, and O’Connell [2]. Table 3.8 Experimental Diffusivities of Electrolytes in Aqueous Solutions Solute Concentration, mol/L Temperature, C Diffusivity, DAB , cm2/s  105 HCl 0.1 12 2.29 HNO3 0.05 20 2.62 0.25 20 2.59 H2 SO4 0.25 20 1.63 KOH 0.01 18 2.20 0.1 18 2.15 1.8 18 2.19 NaOH 0.05 15 1.49 NaCl 0.4 18 1.17 0.8 18 1.19 2.0 18 1.23 KCl 0.4 18 1.46 0.8 18 1.49 2.0 18 1.58 MgSO4 0.4 10 0.39 Ca(NO3 )2 0.14 14 0.85 §3.2 Diffusion Coefficients (Diffusivities) 95

12. Solution At 18.5C, T=334 mB ¼ 291.7=[(334)(1.05)] ¼ 0.832. Using

    Table 3.7, at 25C, the limiting ionic conductances are lþ ¼ 73:5ð0:832Þ ¼ 61:2 and lÀ ¼ 76:3ð0:832Þ ¼ 63:5 From (3-47), D1 ¼ ð8:314Þð291:7Þ½ð1=1Þ þ ð1=1ފ 96;5002½ð1=61:2Þ þ ð1=63:5ފ ¼ 1:62  10À5cm2/s which is 95% of the experimental value. §3.2.4 Diffusivity of Biological Solutes in Liquids The Wilke–Chang equation (3-39) is used for solute molecules of liquid molar volumes up to 500 cm3/mol, which corresponds to molecular weights to almost 600. In biological applications, diffusivities of soluble protein macromolecules having molecu- lar weights greater than 1,000 are of interest. Molecules with molecular weights to 500,000 have diffusivities at 25C that range from 1  10À6 to 1  10À9 cm2/s, which is three orders of magnitude smaller than values of diffusivity for smaller molecules. Data for globular and fibrous protein macromole- cules are tabulated by Sorber [10], with some of these diffusivi- ties given in Table 3.9, which includes diffusivities of two viruses and a bacterium. In the absence of data, the equation of Geankoplis [11], patterned after the Stokes–Einstein equation, can be used to estimate protein diffusivities: DAB ¼ 9:4  10À15T mB ðMA Þ1=3 ð3-48Þ where the units are those of (3-39). Also of interest in biological applications are diffusivities of small, nonelectrolyte molecules in aqueous gels contain- ing up to 10 wt% of molecules such as polysaccharides (agar), which have a tendency to swell. Diffusivities are given by Friedman and Kraemer [12]. In general, the diffu- sivities of small solute molecules in gels are not less than 50% of the values for the diffusivity of the solute in water. §3.2.5 Diffusivity in Solids Diffusion in solids takes place by mechanisms that depend on the diffusing atom, molecule, or ion; the nature of the solid structure, whether it be porous or nonporous, crystalline, or amorphous; and the type of solid material, whether it be metal- lic, ceramic, polymeric, biological, or cellular. Crystalline mate- rials are further classified according to the type of bonding, as molecular, covalent, ionic, or metallic, with most inorganic sol- ids being ionic. Ceramics can be ionic, covalent, or a combina- tion of the two. Molecular solids have relatively weak forces of attraction among the atoms. In covalent solids, such as quartz silica, two atoms share two or more electrons equally. In ionic solids, such as inorganic salts, one atom loses one or more of its electrons by transfer to other atoms, thus forming ions. In metals, positively charged ions are bonded through a field of electrons that are free to move. Diffusion coefficients in solids cover a range of many orders of magnitude. Despite the com- plexity of diffusion in solids, Fick’s first law can be used if a measured diffusivity is available. However, when the diffusing solute is a gas, its solubility in the solid must be known. If the gas dissociates upon dissolution, the concentration of the disso- ciated species must be used in Fick’s law. The mechanisms of diffusion in solids are complex and difficult to quantify. In the next subsections, examples of diffusion in solids are given, Table 3.9 Experimental Diffusivities of Large Biological Materials in Aqueous Solutions MW or Size Configuration T, C Diffusivity, DAB , cm2/s  105 Proteins: Alcohol dehydrogenase 79,070 globular 20 0.0623 Aprotinin 6,670 globular 20 0.129 Bovine serum albumin 67,500 globular 25 0.0681 Cytochrome C 11,990 globular 20 0.130 g–Globulin, human 153,100 globular 20 0.0400 Hemoglobin 62,300 globular 20 0.069 Lysozyme 13,800 globular 20 0.113 Soybean protein 361,800 globular 20 0.0291 Trypsin 23,890 globular 20 0.093 Urease 482,700 globular 25 0.0401 Ribonuclase A 13,690 globular 20 0.107 Collagen 345,000 fibrous 20 0.0069 Fibrinogen, human 339,700 fibrous 20 0.0198 Lipoxidase 97,440 fibrous 20 0.0559 Viruses: Tobacco mosaic virus 40,600,000 rod-like 20 0.0046 T4 bacteriophage 90 nm  200 nm head and tail 22 0.0049 Bacteria: P. aeruginosa $0.5 mm  1.0 mm rod-like, motile ambient 2.1 96 Chapter 3 Mass Transfer and Diffusion

13. together with measured diffusion coefficients that can be used with

    Fick’s first law. Porous solids For porous solids, predictions of the diffusivity of gaseous and liquid solute species in the pores can be made. These methods are considered only briefly here, with details deferred to Chapters 14, 15, and 16, where applications are made to membrane separations, adsorption, and leaching. This type of diffusion is also of importance in the analysis and design of reactors using porous solid catalysts. Any of the following four mass-transfer mechanisms or combina- tions thereof may take place: 1. Molecular diffusion through pores, which present tor- tuous paths and hinder movement of molecules when their diameter is more than 10% of the pore 2. Knudsen diffusion, which involves collisions of diffus- ing gaseous molecules with the pore walls when pore diameter and pressure are such that molecular mean free path is large compared to pore diameter 3. Surface diffusion involving the jumping of molecules, adsorbed on the pore walls, from one adsorption site to another based on a surface concentration-driving force 4. Bulk flow through or into the pores When diffusion occurs only in the fluid in the pores, it is common to use an effective diffusivity, Deff , based on (1) the total cross-sectional area of the porous solid rather than the cross-sectional area of the pore and (2) a straight path, rather than the tortuous pore path. If pore diffusion occurs only by molecular diffusion, Fick’s law (3-3) is used with the effective diffusivity replacing the ordinary diffusion coefficient, DAB : Deff ¼ DAB e t ð3-49Þ where e is the fractional solid porosity (typically 0.5) and t is the pore-path tortuosity (typically 2 to 3), which is the ratio of the pore length to the length if the pore were straight. The effective diffusivity is determined by experiment, or predicted from (3-49) based on measurement of the porosity and tortuos- ity and use of the predictive methods for molecular diffusivity. As an example of the former, Boucher, Brier, and Osburn [13] measured effective diffusivities for the leaching of processed soybean oil (viscosity ¼ 20.1 cP at 120 F) from 1/16-in.-thick porous clay plates with liquid tetrachloroethylene solvent. The rate of extraction was controlled by diffusion of the soybean oil in the clay plates. The measured Deff was 1.0 Â 10À6 cm2/s. Due to the effects of porosity and tortuosity, this value is one order of magnitude less than the molecular diffusivity, DAB , of oil in the solvent. Crystalline solids Diffusion through nonporous crystalline solids depends mark- edly on the crystal lattice structure. As discussed in Chapter 17, only seven different crystal lattice structures exist. For a cubic lattice (simple, body-centered, and face-centered), the diffusivity is equal in all directions (isotropic). In the six other lattice structures (including hexagonal and tetragonal), the dif- fusivity, as in wood, can be anisotropic. Many metals, includ- ing Ag, Al, Au, Cu, Ni, Pb, and Pt, crystallize into the face- centered cubic lattice structure. Others, including Be, Mg, Ti, and Zn, form anisotropic, hexagonal structures. The mecha- nisms of diffusion in crystalline solids include: 1. Direct exchange of lattice position, probably by a ring rotation involving three or more atoms or ions 2. Migration by small solutes through interlattice spaces called interstitial sites 3. Migration to a vacant site in the lattice 4. Migration along lattice imperfections (dislocations), or gain boundaries (crystal interfaces) Diffusion coefficients associated with the first three mech- anisms can vary widely and are almost always at least one order of magnitude smaller than diffusion coefficients in low-viscosity liquids. Diffusion by the fourth mechanism can be faster than by the other three. Experimental diffusivity values, taken mainly from Barrer [14], are given in Table 3.10. The diffusivities cover gaseous, ionic, and metallic sol- utes. The values cover an enormous 26-fold range. Tempera- ture effects can be extremely large. Metals Important applications exist for diffusion of gases through metals. To diffuse through a metal, a gas must first dissolve in the metal. As discussed by Barrer [14], all light gases do Table 3.10 Diffusivities of Solutes in Crystalline Metals and Salts Metal/Salt Solute T, C D, cm2/s Ag Au 760 3.6 Â 10À10 Sb 20 3.5 Â 10À21 Sb 760 1.4 Â 10À9 Al Fe 359 6.2 Â 10À14 Zn 500 2 Â 10À9 Ag 50 1.2 Â 10À9 Cu Al 20 1.3 Â 10À30 Al 850 2.2 Â 10À9 Au 750 2.1 Â 10À11 Fe H2 10 1.66 Â 10À9 H2 100 1.24 Â 10À7 C 800 1.5 Â 10À8 Ni H2 85 1.16 Â 10À8 H2 165 1.05 Â 10À7 CO 950 4 Â 10À8 W U 1727 1.3 Â 10À11 AgCl Ag+ 150 2.5 Â 10À14 Ag+ 350 7.1 Â 10À8 ClÀ 350 3.2 Â 10À16 KBr H2 600 5.5 Â 10À4 Br2 600 2.64 Â 10À4 §3.2 Diffusion Coefficients (Diffusivities) 97

14. not dissolve in all metals. Hydrogen dissolves in Cu, Al,

    Ti, Ta, Cr, W, Fe, Ni, Pt, and Pd, but not in Au, Zn, Sb, and Rh. Nitrogen dissolves in Zr but not in Cu, Ag, or Au. The noble gases do not dissolve in common metals. When H2 , N2 , and O2 dissolve in metals, they dissociate and may react to form hydrides, nitrides, and oxides. Molecules such as ammonia, carbon dioxide, carbon monoxide, and sulfur dioxide also dissociate. Example 3.9 illustrates how hydro- gen gas can slowly leak through the wall of a small, thin pressure vessel. EXAMPLE 3.9 Diffusion of Hydrogen in Steel. Hydrogen at 200 psia and 300C is stored in a 10-cm-diameter steel pressure vessel of wall thickness 0.125 inch. Solubility of hydrogen in steel, which is proportional to the square root of the hydrogen partial pressure, is 3.8  10À6 mol/cm3 at 14.7 psia and 300C. The diffusivity of hydrogen in steel at 300C is 5  10À6 cm2/s. If the inner surface of the vessel wall remains saturated at the hydrogen partial pressure and the hydrogen partial pressure at the outer sur- face is zero, estimate the time for the pressure in the vessel to decrease to 100 psia because of hydrogen loss. Solution Integrating Fick’s first law, (3-3), where A is H2 and B is the metal, assuming a linear concentration gradient, and equating the flux to the loss of hydrogen in the vessel, À dnA dt ¼ DAB ADcA Dz ð1Þ Because pA ¼ 0 outside the vessel, DcA ¼ cA ¼ solubility of A at the inside wall surface in mol/cm3 and cA ¼ 3:8  10À6 p A 14:7   0:5 , where pA is the pressure of A inside the vessel in psia. Let p Ao and nAo be the initial pressure and moles of A in the vessel. Assuming the ideal-gas law and isothermal conditions, nA ¼ nAo p A =p Ao ð2Þ Differentiating (2) with respect to time, dnA dt ¼ nAo p Ao dp A dt ð3Þ Combining (1) and (3), dp A dt ¼ À DAB Að3:8  10À6Þp0:5 A p Ao nAo Dzð14:7Þ0:5 ð4Þ Integrating and solving for t, t ¼ 2nAo Dzð14:7Þ0:5 3:8  10À6DAB Ap Ao ðp0:5 Ao À p0:5 A Þ Assuming the ideal-gas law, nAo ¼ ð200=14:7Þ½ð3:14  103Þ=6Š 82:05ð300 þ 273Þ ¼ 0:1515 mol The mean-spherical shell area for mass transfer, A, is A ¼ 3:14 2 ð10Þ2 þ ð10:635Þ2 h i ¼ 336 cm2 The time for the pressure to drop to 100 psia is t ¼ 2ð0:1515Þð0:125  2:54Þð14:7Þ0:5 3:8  10À6ð5  10À6Þð336Þð200Þ ð2000:5 À 1000:5Þ ¼ 1:2  106 s or 332 h Silica and glass Another area of interest is diffusion of light gases through silica, whose two elements, Si and O, make up about 60% of the earth’s crust. Solid silica exists in three crystalline forms (quartz, tridymite, and cristobalite) and in various amorphous forms, including fused quartz. Table 3.11 includes diffusivit- ies, D, and solubilities as Henry’s law constants, H, at 1 atm for helium and hydrogen in fused quartz as calculated from correlations of Swets, Lee, and Frank [15] and Lee [16]. The product of diffusivity and solubility is the permeability, PM . Thus, PM ¼ DH ð3-50Þ Unlike metals, where hydrogen usually diffuses as the atom, hydrogen diffuses as a molecule in glass. For hydrogen and helium, diffusivities increase rapidly with temperature. At ambient temperature they are three orders of magnitude smaller than they are in liquids. At high temperatures they approach those in liquids. Solubilities vary slowly with temperature. Hydrogen is orders of magnitude less soluble in glass than helium. Diffusivities for oxygen are included in Table 3.11 from studies by Williams [17] and Sucov [18]. At 1000C, the two values differ widely because, as discussed by Kingery, Bowen, and Uhlmann [19], in the former case, transport occurs by molecular diffusion, while in the latter, transport is by slower network diffusion as oxy- gen jumps from one position in the network to another. The activation energy for the latter is much larger than that for the former (71,000 cal/mol versus 27,000 cal/mol). The choice of glass can be critical in vacuum operations because of this wide range of diffusivity. Ceramics Diffusion in ceramics has been the subject of numerous studies, many of which are summarized in Figure 3.4, which Table 3.11 Diffusivities and Solubilities of Gases in Amorphous Silica at 1 atm Gas Temp, oC Diffusivity, cm2/s Solubility mol/cm3-atm He 24 2.39  10À8 1.04  10À7 300 2.26  10À6 1.82  10À7 500 9.99  10À6 9.9  10À8 1,000 5.42  10À5 1.34  10À7 H2 300 6.11  10À8 3.2  10À14 500 6.49  10À7 2.48  10À13 1,000 9.26  10À6 2.49  10À12 O2 1,000 6.25  10À9 (molecular) 1,000 9.43  10À15 (network) 98 Chapter 3 Mass Transfer and Diffusion

15. is from Kingery et al. [19], where diffusivity is plotted

    as a function of the inverse of temperature in the high-tempera- ture range. In this form, the slopes of the curves are propor- tional to the activation energy for diffusion, E, where D ¼ Do exp À E RT   ð3-51Þ An insert in Figure 3.4 relates the slopes of the curves to acti- vation energy. The diffusivity curves cover a ninefold range from 10À6 to 10À15 cm2/s, with the largest values correspond- ing to the diffusion of potassium in b-Al2 O3 and one of the smallest for the diffusion of carbon in graphite. As discussed in detail by Kingery et al. [19], diffusion in crystalline oxides depends not only on temperature but also on whether the ox- ide is stoichiometric or not (e.g., FeO and Fe0.95 O) and on impurities. Diffusion through vacant sites of nonstoichiomet- ric oxides is often classified as metal-deficient or oxygen- deficient. Impurities can hinder diffusion by filling vacant lat- tice or interstitial sites. Polymers Diffusion through nonporous polymers is dependent on the type of polymer, whether it be crystalline or amorphous and, if the latter, glassy or rubbery. Commercial crystalline poly- mers are about 20% amorphous, and it is through these regions that diffusion occurs. As with the transport of gases through metals, transport through polymer membranes is characterized by the solution-diffusion mechanism of (3-50). Fick’s first law, in the following integrated forms, is then applied to compute the mass-transfer flux. Gas species: Ni ¼ Hi Di z2 À z1 ðpi1 À pi2 Þ ¼ PMi z2 À z1 ðpi1 À pi2 Þ ð3-52Þ where pi is the partial pressure at a polymer surface. 10–5 1716 Co in CoO (air) Mg in MgO (single) Ni in NiO (air) Fe in Fe0.95 O in Ca0.14 Zr0.86 O1.86 O in Y2 O3 Cr in Cr2 O3 kJ/mol O in UO2.00 Ca in CaO C in graphite O in MgO U in UO2.00 Y in Y2 O3 Al in Al2 O3 O in Al2 O3 (single) O in Al2 O3 (poly) N in U N O in Cu2 O (Po2 = 20 kPa) 763 382 191 133 90.8 57.8 O in Cu2 O (Po2 = 14 kPa) K in –Al2 O3 β 1393 1145 977 828 727 Temperature, °C 0.5 0.4 0.6 0.7 0.8 0.9 1.0 1.1 1/T × 1000/T, K–1 Diffusion coefficient, cm2/s 10–6 10–7 10–8 10–9 10–10 10–11 10–12 10–13 10–14 10–15 O in CoO (Po2 = 20 kPa) O fused SiO2 (Po2 = 101 kPa) O in TiO2 (Po2 = 101 kPa) O in Ni0.68 Fe2.32 O4 (single) O in Cr2 O3 Figure 3.4 Diffusion coefficients for single and polycrystalline ceramics. [From W.D. Kingery, H.K. Bowen, and D.R. Uhlmann, Introduction to Ceramics, 2nd ed., Wiley Interscience, New York (1976) with permission.] §3.2 Diffusion Coefficients (Diffusivities) 99

16. Liquid species: Ni ¼ Ki Di z2 À z1 ðci1

    À ci2 Þ ð3-53Þ where Ki, the equilibrium partition coefficient, is the ratio of the concentration in the polymer to the concentration, ci, in the liquid at the polymer surface. The product Ki Di is the liq- uid permeability. Diffusivities for light gases in four polymers, given in Table 14.6, range from 1.3  10À9 to 1.6  10À6 cm2/s, which is magnitudes less than for diffusion in a gas. Diffusivity of liquids in rubbery polymers has been stud- ied as a means of determining viscoelastic parameters. In Table 3.12, taken from Ferry [20], diffusivities are given for solutes in seven different rubber polymers at near-ambient conditions. The values cover a sixfold range, with the largest diffusivity being that for n-hexadecane in polydimethylsilox- ane. The smallest diffusivities correspond to the case in which the temperature approaches the glass-transition tem- perature, where the polymer becomes glassy in structure. This more rigid structure hinders diffusion. As expected, smaller molecules have higher diffusivities. A study of n- hexadecane in styrene-butadiene copolymers at 25C by Rhee and Ferry [21] shows a large effect on diffusivity of polymer fractional free volume. Polymers that are 100% crystalline permit little or no dif- fusion of gases and liquids. The diffusivity of methane at 25C in polyoxyethylene oxyisophthaloyl decreases from 0.30  10À9 to 0.13  10À9 cm2/s when the degree of crys- tallinity increases from 0 to 40% [22]. A measure of crystal- linity is the polymer density. The diffusivity of methane at 25C in polyethylene decreases from 0.193  10À6 to 0.057  10À6 cm2/s when specific gravity increases from 0.914 to 0.964 [22]. Plasticizers cause diffusivity to increase. When polyvinylchloride is plasticized with 40% tricresyl tri- phosphate, the diffusivity of CO at 27oC increases from 0.23  10À8 to 2.9  10À8 cm2/s [22]. EXAMPLE 3.10 Diffusion of Hydrogen through a Membrane. Hydrogen diffuses through a nonporous polyvinyltrimethylsilane membrane at 25C. The pressures on the sides of the membrane are 3.5 MPa and 200 kPa. Diffusivity and solubility data are given in Table 14.9. If the hydrogen flux is to be 0.64 kmol/m2-h, how thick in micrometers (mm) should the membrane be? Solution Equation (3-52) applies. From Table 14.9, D ¼ 160  10À11m2/s; H ¼ S ¼ 0:54  10À4mol/m3-Pa From (3-50), PM ¼ DH ¼ ð160  10À11Þð0:64  10À4Þ ¼ 86:4  10À15mol/m-s-Pa p 1 ¼ 3:5  106 Pa; p 2 ¼ 0:2  106 Pa Membrane thickness ¼ z2 À z1 ¼ Dz ¼ PM ðp 1 À p 2 Þ=N Dz ¼ 86:4  10À15ð3:5  106 À 0:2  106Þ ½0:64ð1000Þ=3600Š ¼ 1:6  10À6m ¼ 1:6 mm Membranes must be thin to achieve practical permeation rates. Cellular solids and wood A widely used cellular solid is wood, whose structure is dis- cussed by Gibson and Ashby [23]. Chemically, wood consists of lignin, cellulose, hemicellulose, and minor amounts of Table 3.12 Diffusivities of Solutes in Rubbery Polymers Polymer Solute Temperature, K Diffusivity, cm2/s Polyisobutylene n-Butane 298 1.19  10À9 i-Butane 298 5.3  10À10 n-Pentane 298 1.08  10À9 n-Hexadecane 298 6.08  10À10 Hevea rubber n-Butane 303 2.3  10À7 i-Butane 303 1.52  10À7 n-Pentane 303 2.3  10À7 n-Hexadecane 298 7.66  10À8 Polymethylacrylate Ethyl alcohol 323 2.18  10À10 Polyvinylacetate n-Propyl alcohol 313 1.11  10À12 n-Propyl chloride 313 1.34  10À12 Ethyl chloride 343 2.01  10À9 Ethyl bromide 343 1.11  10À9 Polydimethylsiloxane n-Hexadecane 298 1.6  10À6 1,4-Polybutadiene n-Hexadecane 298 2.21  10À7 Styrene-butadiene rubber n-Hexadecane 298 2.66  10À8 100 Chapter 3 Mass Transfer and Diffusion

17. organic chemicals and elements. The latter are extractable, and the

    former three, which are all polymers, give wood its struc- ture. Green wood also contains up to 25 wt% moisture in the cell walls and cell cavities. Adsorption or desorption of mois- ture in wood causes anisotropic swelling and shrinkage. Wood often consists of (1) highly elongated hexagonal or rectangular cells, called tracheids in softwood (coniferous species, e.g., spruce, pine, and fir) and fibers in hardwood (deciduous or broad-leaf species, e.g., oak, birch, and wal- nut); (2) radial arrays of rectangular-like cells, called rays; and (3) enlarged cells with large pore spaces and thin walls, called sap channels because they conduct fluids up the tree. Many of the properties of wood are anisotropic. For example, stiffness and strength are 2 to 20 times greater in the axial direction of the tracheids or fibers than in the radial and tangential directions of the trunk. This anisot- ropy extends to permeability and diffusivity of wood pene- trants, such as moisture and preservatives. According to Stamm [24], the permeability of wood to liquids in the axial direction can be up to 10 times greater than in the transverse direction. Movement of liquids and gases through wood occurs dur- ing drying and treatment with preservatives, fire retardants, and other chemicals. It takes place by capillarity, pressure permeability, and diffusion. All three mechanisms of move- ment of gases and liquids in wood are considered by Stamm [24]. Only diffusion is discussed here. The simplest form of diffusion is that of a water-soluble solute through wood saturated with water, so no dimen- sional changes occur. For the diffusion of urea, glycerine, and lactic acid into hardwood, Stamm [24] lists diffusivities in the axial direction that are 50% of ordinary liquid diffu- sivities. In the radial direction, diffusivities are 10% of the axial values. At 26.7C, the diffusivity of zinc sulfate in water is 5 Â 10À6 cm2/s. If loblolly pine sapwood is impregnated with zinc sulfate in the radial direction, the diffusivity is 0.18 Â 10À6 cm2/s [24]. The diffusion of water in wood is complex. Water is held in the wood in different ways. It may be physically adsorbed on cell walls in monomolecular layers, condensed in preex- isting or transient cell capillaries, or absorbed into cell walls to form a solid solution. Because of the practical importance of lumber drying rates, most diffusion coefficients are measured under drying conditions in the radial direction across the fibers. Results de- pend on temperature and specific gravity. Typical results are given by Sherwood [25] and Stamm [24]. For example, for beech with a swollen specific gravity of 0.4, the diffusivity increases from a value of 1 Â 10À6 cm2/s at 10C to 10 Â 10À6 cm2/s at 60C. §3.3 STEADY- AND UNSTEADY-STATE MASS TRANSFER THROUGH STATIONARY MEDIA Mass transfer occurs in (1) stagnant or stationary media, (2) fluids in laminar flow, and (3) fluids in turbulent flow, each requiring a different calculation procedure. The first is pre- sented in this section, the other two in subsequent sections. Fourier’s law is used to derive equations for the rate of heat transfer by conduction for steady-state and unsteady- state conditions in stationary media consisting of shapes such as slabs, cylinders, and spheres. Analogous equations can be derived for mass transfer using Fick’s law. In one dimension, the molar rate of mass transfer of A in a binary mixture is given by a modification of (3-12), which includes bulk flow and molecular diffusion: nA ¼ xA ðnA þ nB Þ À cDAB A dxA dz   ð3-54Þ If A is undergoing mass transfer but B is stationary, nB ¼ 0. It is common to assume that c is a constant and xA is small. The bulk-flow term is then eliminated and (3-54) becomes Fick’s first law: nA ¼ ÀcDAB A dxA dz   ð3-55Þ Alternatively, (3-55) can be written in terms of a concentra- tion gradient: nA ¼ ÀDAB A dcA dz   ð3-56Þ This equation is analogous to Fourier’s law for the rate of heat conduction, Q: Q ¼ ÀkA dT dz   ð3-57Þ §3.3.1 Steady-State Diffusion For steady-state, one-dimensional diffusion with constant DAB , (3-56) can be integrated for various geometries, the results being analogous to heat conduction. 1. Plane wall with a thickness, z2 À z1 : nA ¼ DAB A cA1 À cA2 z2 À z2   ð3-58Þ 2. Hollow cylinder of inner radius r1 and outer radius r2 , with diffusion in the radial direction outward: nA ¼ 2pL DAB ðcA1 À cA2 Þ lnðr2 =r1 Þ ð3-59Þ or nA ¼ DAB ALM cA1 À cA2 r2 À r1   ð3-60Þ where ALM ¼ log mean of the areas 2prL at r1 and r2 L ¼ length of the hollow cylinder 3. Spherical shell of inner radius r1 and outer radius r2 , with diffusion in the radial direction outward: nA ¼ 4pr1 r2 DAB ðcA1 À cA2 Þ r2 À r1 ð3-61Þ §3.3 Steady- and Unsteady-State Mass Transfer through Stationary Media 101

18. or nA ¼ DAB AGM cA1 À cA2 r2 À

    r1   ð3-62Þ where AGM ¼ geometric mean of the areas 4pr2. When r1 =r2 < 2, the arithmetic mean area is no more than 4% greater than the log mean area. When r1 =r2 < 1.33, the arithmetic mean area is no more than 4% greater than the geometric mean area. §3.3.2 Unsteady-State Diffusion Consider one-dimensional molecular diffusion of species A in stationary B through a differential control volume with dif- fusion in the z-direction only, as shown in Figure 3.5. Assume constant diffusivity and negligible bulk flow. The molar flow rate of species A by diffusion in the z-direction is given by (3-56): nAz ¼ ÀDAB A qcA qz   z ð3-63Þ At the plane, z ¼ z þ Dz, the diffusion rate is nAzþDz ¼ ÀDAB A qcA qz   zþDz ð3-64Þ The accumulation of species A in the control volume is A qcA qt Dz ð3-65Þ Since rate in – rate out ¼ accumulation, ÀDAB A qcA qz   z þ DAB A qcA qz   zþDz ¼ A qcA qt   Dz ð3-66Þ Rearranging and simplifying, DAB ðqcA =qzÞ zþDz À ðqcA =qzÞ z Dz ! ¼ qcA qt ð3-67Þ In the limit, as Dz ! 0, qcA qt ¼ DAB q2cA qz2 ð3-68Þ Equation (3-68) is Fick’s second law for one-dimensional diffusion. The more general form for three-dimensional rectangular coordinates is qcA qt ¼ DAB q2cA qx2 þ q2cA qy2 þ q2cA qz2   ð3-69Þ For one-dimensional diffusion in the radial direction only for cylindrical and spherical coordinates, Fick’s second law becomes, respectively, qcA qt ¼ DAB r q qr r qcA qr   ð3-70Þ and qcA qt ¼ DAB r2 q qr r2 qcA qr   ð3-71Þ Equations (3-68) to (3-71) are analogous to Fourier’s sec- ond law of heat conduction, where cA is replaced by tempera- ture, T, and diffusivity, DAB , by thermal diffusivity, a ¼ k=rCP . The analogous three equations for heat conduction for constant, isotropic properties are, respectively: qT qt ¼ a q2T qx2 þ q2T qy2 þ q2T qz2   ð3-72Þ qT qt ¼ a r q qr r qT qr   ð3-73Þ qT qt ¼ a r2 q qr r2 qT qr   ð3-74Þ Analytical solutions to these partial differential equations in either Fick’s-law or Fourier’s-law form are available for a variety of boundary conditions. They are derived and discussed by Carslaw and Jaeger [26] and Crank [27]. §3.3.3 Diffusion in a Semi-infinite Medium Consider the semi-infinite medium shown in Figure 3.6, which extends in the z-direction from z ¼ 0 to z ¼ 1. The x and y coordinates extend from À1 to þ1 but are not of interest because diffusion is assumed to take place only in the z-direction. Thus, (3-68) applies to the region z ! 0. At time t 0, the concentration is cAo for z ! 0. At t ¼ 0, the surface of the semi-infinite medium at z ¼ 0 is instantaneously brought to the concentration cAs >cAo and held there for t > 0, causing diffusion into the medium to occur. Because the medium is infinite in the z-direction, diffusion cannot extend to z ¼ 1 and, therefore, as z ! 1, cA ¼ cAo for all t ! 0. Because (3-68) and its one boundary (initial) condition in time and two boundary conditions in distance are linear in the dependent variable, cA , an exact solution can be obtained by combination of variables [28] or the Laplace transform method [29]. The result, in terms of fractional concentration change, is u ¼ cA À cAo cAs À cAo ¼ erfc z 2 ffiffiffiffiffiffiffiffiffiffi DAB t p   ð3-75Þ nAz = –DAB A Flow in Flow out Accumulation z ∂ ∂ A dz cA t ∂ ∂ nAz+Δz = –DAB A z+Δz z z+Δz ∂ cA z cA z ∂ Figure 3.5 Unsteady-state diffusion through a volume A dz. z Direction of diffusion Figure 3.6 One-dimensional diffusion into a semi-infinite medium. 102 Chapter 3 Mass Transfer and Diffusion

19. where the complementary error function, erfc, is related to the

    error function, erf, by erfcðxÞ ¼ 1 À erfðxÞ ¼ 1 À 2 ffiffiffiffi p p Z x 0 eÀh2 dh ð3-76Þ The error function is included in most spreadsheet programs and handbooks, such as Handbook of Mathematical Functions [30]. The variation of erf(x) and erfc(x) is: x erf(x) erfc(x) 0 0.0000 1.0000 0.5 0.5205 0.4795 1.0 0.8427 0.1573 1.5 0.9661 0.0339 2.0 0.9953 0.0047 1 1.0000 0.0000 Equation (3-75) determines the concentration in the semi- infinite medium as a function of time and distance from the surface, assuming no bulk flow. It applies rigorously to diffu- sion in solids, and also to stagnant liquids and gases when the medium is dilute in the diffusing solute. In (3-75), when ðz=2 ffiffiffiffiffiffiffiffiffiffi DAB t p Þ ¼ 2, the complementary error function is only 0.0047, which represents less than a 1% change in the ratio of the concentration change at z ¼ z to the change at z ¼ 0. It is common to call z ¼ 4 ffiffiffiffiffiffiffiffiffiffi DAB t p the penetra- tion depth, and to apply (3-75) to media of finite thickness as long as the thickness is greater than the penetration depth. The instantaneous rate of mass transfer across the surface of the medium at z ¼ 0 can be obtained by taking the deriva- tive of (3-75) with respect to distance and substituting it into Fick’s first law applied at the surface of the medium. Then, using the Leibnitz rule for differentiating the integral of (3-76), with x ¼ z=2 ffiffiffiffiffiffiffiffiffiffi DAB t p , nA ¼ ÀDAB A qcA qz   z¼0 ¼ DAB A cAs À cAo ffiffiffiffiffiffiffiffiffiffiffiffiffiffi pDAB t p   exp À z2 4DAB t      z¼0 ð3-77Þ Thus, nA jz¼0 ¼ ffiffiffiffiffiffiffiffiffi DAB pt r AðcAs À cAo Þ ð3-78Þ The total number of moles of solute, N A, transferred into the semi-infinite medium is obtained by integrating (3-78) with respect to time: N A ¼ Z t o nA jz¼0 dt ¼ ffiffiffiffiffiffiffiffiffi DAB p r AðcAs À cAo Þ Z t o dt ffiffi t p ¼ 2AðcAs À cAo Þ ffiffiffiffiffiffiffiffiffiffi DAB t p r ð3-79Þ EXAMPLE 3.11 Rates of Diffusion in Stagnant Media. Determine how long it will take for the dimensionless concentration change, u ¼ ðcA À cAo Þ=ðcAs À cAo Þ, to reach 0.01 at a depth z ¼ 100 cm in a semi-infinite medium. The medium is initially at a solute concentration cAo , after the surface concentration at z ¼ 0 increases to cAs , for diffusivities representative of a solute diffusing through a stagnant gas, a stagnant liquid, and a solid. Solution For a gas, assume DAB ¼ 0.1 cm2/s. From (3-75) and (3-76), u ¼ 0:01 ¼ 1 À erf z 2 ffiffiffiffiffiffiffiffiffiffi DAB t p   Therefore, erf z 2 ffiffiffiffiffiffiffiffiffiffi DAB t p   ¼ 0:99 From tables of the error function, z 2 ffiffiffiffiffiffiffiffiffiffi DAB t p   ¼ 1:8214 Solving, t ¼ 100 1:8214ð2Þ ! 2 1 0:10 ¼ 7;540 s ¼ 2:09 h In a similar manner, the times for typical gas, liquid, and solid me- dia are found to be drastically different, as shown below. Semi-infinite Medium DAB , cm2/s Time for u ¼ 0.01 at 1 m Gas 0.10 2.09 h Liquid 1  10À5 2.39 year Solid 1  10À9 239 centuries The results show that molecular diffusion is very slow, especially in liquids and solids. In liquids and gases, the rate of mass transfer can be greatly increased by agitation to induce turbulent motion. For sol- ids, it is best to reduce the size of the solid. §3.3.4 Medium of Finite Thickness with Sealed Edges Consider a rectangular, parallelepiped stagnant medium of thickness 2a in the z-direction, and either infinitely long dim- ensions in the y- and x-directions or finite lengths 2b and 2c. Assume that in Figure 3.7a the edges parallel to the z- direction are sealed, so diffusion occurs only in the z-direction, and that initially, the concentration of the solute in the medium is uniform at cAo . At time t ¼ 0, the two unsealed surfaces at z ¼ Æa are brought to and held at concentration cAs > cAo . Because of symmetry, qcA =qz ¼ 0 at z ¼ 0. Assume constant DAB . Again (3-68) applies, and an exact solution can be obtained because both (3-68) and the boundary conditions are linear in cA . The result from Carslaw and Jaeger [26], in terms of the fractional, unaccomplished concentration change, E, is E ¼ 1 À u ¼ cAs À cA cAs À cAo ¼ 4 p X 1 n¼0 ðÀ1Þn ð2n þ 1Þ Â exp ÀDAB ð2n þ 1Þ2p2t=4a2 h i cos ð2n þ 1Þpz 2a ð3-80Þ §3.3 Steady- and Unsteady-State Mass Transfer through Stationary Media 103

20. or, in terms of the complementary error function, E ¼

    1 À u ¼ cAs À cA cAs À cAo ¼ X 1 n¼0 ðÀ1Þn  erfc ð2n þ 1Þa À z 2 ffiffiffiffiffiffiffiffiffiffi DAB t p þ erfc ð2n þ 1Þa þ z 2 ffiffiffiffiffiffiffiffiffiffi DAB t p ! ð3-81Þ For large values of DAB t=a2, called the Fourier number for mass transfer, the infinite series solutions of (3-80) and (3-81) converge rapidly, but for small values (e.g., short times), they do not. However, in the latter case, the solution for the semi-infinite medium applies for DAB t=a2 < 1 16 . A plot of the solution is given in Figure 3.8. The instantaneous rate of mass transfer across the surface of either unsealed face of the medium (i.e., at z ¼ Æa) is obtained by differentiating (3-80) with respect to z, evaluating the result at z ¼ a, and substituting into Fick’s first law to give nA jz¼a ¼ 2DAB ðcAs À cAo ÞA a  X 1 n¼0 exp À DAB ð2n þ 1Þ2p2t 4a2 " # ð3-82Þ The total moles transferred across either unsealed face is determined by integrating (3-82) with respect to time: N A ¼ Z t o nA jz¼a dt ¼ 8ðcAs À cAo ÞAa p2  X 1 n¼0 1 ð2n þ 1Þ2 1 À exp À DAB ð2n þ 1Þ2p2t 4a2 " # ( ) ð3-83Þ For a slab, the average concentration of the solute cAavg , as a function of time, is cAs À cAavg cAs À cAo ¼ Ra o ð1 À uÞdz a ð3-84Þ Substitution of (3-80) into (3-84), followed by integration, gives Eavgslab ¼ ð1 À uave Þ slab ¼ cAs À cAavg cAs À cAo ¼ 8 p2 X 1 n¼0 1 ð2n þ 1Þ2 exp À DAB ð2n þ 1Þ2p2t 4a2 " # ð3-85Þ This equation is plotted in Figure 3.9. The concentrations are in mass of solute per mass of dry solid or mass of solute/vol- ume. This assumes that during diffusion, the solid does not shrink or expand; thus, the mass of dry solid per unit volume of wet solid remains constant. In drying it is common to express moisture content on a dry-solid basis. When the edges of the slab in Figure 3.7a are not sealed, the method of Newman [31] can be used with (3-69) to deter- mine concentration changes within the slab. In this method, c c x z a a y b b x Two circular ends at x = +c and –c are sealed. (b) Cylinder. Edges at x = +c and –c and at y = +b and –b are sealed. (a) Slab. (c) Sphere r a r a c c Figure 3.7 Unsteady-state diffusion in media of finite dimensions. 1.0 0.8 0.6 0.4 0.2 0 0 0.2 0.4 0.6 0.8 1.0 1.0 Center of slab 0.6 0.4 0.2 0.1 0.04 0 0.2 0.4 0.6 z a 0.8 1.0 0.01 cA – cAo cAs – cAo = 1 – E cAs – cA cAs – cAo = E DAB t/a2 Surface of slab Figure 3.8 Concentration profiles for unsteady-state diffusion in a slab. Adapted from H.S. Carslaw and J.C. Jaeger, Conduction of Heat in Solids, 2nd ed., Oxford University Press, London (1959).] 104 Chapter 3 Mass Transfer and Diffusion

21. E or Eavg is given in terms of E values

    from the solution of (3-68) for each of the coordinate directions by E ¼ Ex Ey Ez ð3-86Þ Corresponding solutions for infinitely long, circular cylinders and spheres are available in Carslaw and Jaeger [26] and are plotted in Figures 3.9 to 3.11. For a short cylinder whose ends are not sealed, E or Eavg is given by the method of Newman as E ¼ Er Ex ð3-87Þ For anisotropic materials, Fick’s second law in the form of (3-69) does not hold. Although the general anisotropic case is exceedingly complex, as shown in the following example, its mathematical treatment is relatively simple when the princi- pal axes of diffusivity coincide with the coordinate system. EXAMPLE 3.12 Diffusion of Moisture from Lumber. A board of lumber 5 Â 10 Â 20 cm initially contains 20 wt% mois- ture. At time zero, all six faces are brought to an equilibrium mois- ture content of 2 wt%. Diffusivities for moisture at 25C are 2 Â 10À5 cm2/s in the axial (z) direction along the fibers and 4 Â 10À6 cm2/s in the two directions perpendicular to the fibers. Calculate the time in hours for the average moisture content to drop to 5 wt% at 25C. At that time, determine the moisture content at the center of the slab. All moisture contents are on a dry basis. Solution In this case, the solid is anisotropic, with Dx ¼ Dy ¼ 4 Â 10À6 cm2/s and Dz ¼ 2 Â 10À5 cm2/s, where dimensions 2c, 2b, and 2a in the x-, y-, and z-directions are 5, 10, and 20 cm, respectively. Fick’s second law for an isotropic medium, (3-69), must be rewritten as qcA qt ¼ Dx q2cA qx2 þ q2cA qy2 ! þ Dz q2cA qz2 ð1Þ To transform (1) into the form of (3-69) [26], let x1 ¼ x ffiffiffiffiffiffi D Dx r ; y 1 ¼ y ffiffiffiffiffiffi D Dx r ; z1 ¼ z ffiffiffiffiffiffi D Dz r ð2Þ E a, E b, E c (slab) E r (cylinder) E s (sphere) DAB t/a2, DAB t/b2, DAB t/c2 0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 1.0 0.8 0.6 0.4 0.3 0.2 0.10 0.08 0.06 0.04 0.03 0.02 0.010 0.008 0.006 0.004 0.003 0.002 0.001 2c 2a 2a 2c 2a 2b E avg = cAs – cAavg cAs – cAo Figure 3.9 Average concentrations for unsteady-state diffusion. [Adapted from R.E. Treybal, Mass-Transfer Operations, 3rd ed., McGraw- Hill, New York (1980).] r a DAB t/a2 0 0.2 0.4 0.6 0.8 1.0 = 1 – E cA – cAo cAs – cAo 0.4 0.2 0.1 0.04 0.01 0 0.2 0.4 0.6 0.8 1.0 1.0 0.8 0.6 0.4 0.2 0 Axis of cylinder cAs – cA cAs – cAo = E Surface of cylinder Figure 3.10 Concentration profiles for unsteady-state diffusion in a cylinder. [Adapted from H.S. Carslaw and J.C. Jaeger, Conduction of Heat in Solids, 2nd ed., Oxford University Press, London (1959).] r a DAB t/a2 0 0.2 0.4 0.6 0.8 1.0 = 1 – E cA – cAo cAs – cAo 0.4 0.2 0.1 0.04 0.01 0 0.2 0.4 0.6 0.8 1.0 1.0 0.8 0.6 0.4 0.2 0 Center of sphere cAs – cA cAs – cAo = E Surface of sphere Figure 3.11 Concentration profiles for unsteady-state diffusion in a sphere. [Adapted from H.S. Carslaw and J.C. Jaeger, Conduction of Heat in Solids, 2nd ed., Oxford University Press, London (1959).] §3.3 Steady- and Unsteady-State Mass Transfer through Stationary Media 105

22. where D is arbitrarily chosen. With these changes, (1) becomes

    qcA qt ¼ D q2cA qx2 1 þ q2cA qy2 1 þ q2cA qz2 1   ð3Þ This is the same form as (3-69), and since the boundary conditions do not involve diffusivities, Newman’s method applies, using Figure 3.9, where concentration cA is replaced by weight-percent moisture on a dry basis. From (3-86) and (3-85), Eaveslab ¼ Eavgx Eavgy Eavgz ¼ cAave À cAs cAo À cAs ¼ 5 À 2 20 À 2 ¼ 0:167 Let D ¼ 1 Â 10À5 cm2/s. z 1 Direction (axial): a1 ¼ a D Dz   1=2 ¼ 20 2 1 Â 10À5 2 Â 10À5  1=2 ¼ 7:07 cm Dt a2 1 ¼ 1 Â 10À5t 7:072 ¼ 2:0 Â 10À7t; s y1 Direction: b1 ¼ b D Dy   1=2 ¼ 20 2 1 Â 10À5 4 Â 10À6  1=2 ¼ 7:906 cm Dt b2 1 ¼ 1 Â 10À5t 7:9062 ¼ 1:6 Â 10À7t; s x1 Direction: c1 ¼ c D Dx   1=2 ¼ 5 2 1 Â 10À5 4 Â 10À6  1=2 ¼ 3:953 cm Dt c2 1 ¼ 1 Â 10À5t 3:9532 ¼ 6:4 Â 10À7t; s Figure 3.9 is used iteratively with assumed values of time in seconds to obtain values of Eavg for each of the three coordinates until (3-86) equals 0.167. t, h t, s Eavgz1 Eavgy1 Eavgx1 Eavg 100 360,000 0.70 0.73 0.46 0.235 120 432,000 0.67 0.70 0.41 0.193 135 486,000 0.65 0.68 0.37 0.164 Therefore, it takes approximately 136 h. For 136 h ¼ 490,000 s, Fourier numbers for mass transfer are Dt a2 1 ¼ ð1 Â 10À5Þð490;000Þ 7:072 ¼ 0:0980 Dt b2 1 ¼ ð1 Â 10À5Þð490;000Þ 7:9062 ¼ 0:0784 Dt c2 1 ¼ ð1 Â 10À5Þð490;000Þ 3:9532 ¼ 0:3136 From Figure 3.8, at the center of the slab, Ecenter ¼ Ez1 Ey 1 Ex1 ¼ ð0:945Þð0:956Þð0:605Þ ¼ 0:547 ¼ cAs À cAcenter cAs À cAo ¼ 2 À cAcenter 2 À 20 ¼ 0:547 Solving, cA at the center = 11.8 wt% moisture §3.4 MASS TRANSFER IN LAMINAR FLOW Many mass-transfer operations involve diffusion in fluids in laminar flow. As with convective heat-transfer in laminar flow, the calculation of such operations is amenable to well- defined theory. This is illustrated in this section by three common applications: (1) a fluid falling as a film down a wall; (2) a fluid flowing slowly along a horizontal, flat plate; and (3) a fluid flowing slowly through a circular tube, where mass transfer occurs, respectively, between a gas and the fall- ing liquid film, from the surface of the flat plate into the flow- ing fluid, and from the inside surface of the tube into the flowing fluid. §3.4.1 Falling Laminar, Liquid Film Consider a thin liquid film containing A and nonvolatile B, falling in laminar flow at steady state down one side of a ver- tical surface and exposed to pure gas, A, which diffuses into the liquid, as shown in Figure 3.12. The surface is infinitely wide in the x-direction (normal to the page), flow is in the downward y-direction, and mass transfer of A is in the z- direction. Assume that the rate of mass transfer of A into the liquid film is so small that the liquid velocity in the z- direction, uz, is zero. From fluid mechanics, in the absence of end effects the equation of motion for the liquid film in fully developed laminar flow in the y-direction is m d2uy dz2 þ rg ¼ 0 ð3-88Þ Usually, fully developed flow, where uy is independent of the distance y, is established quickly. If d is the film thickness and the boundary conditions are uy ¼ 0 at z ¼ d (no slip at the solid surface) and duy =dz ¼ 0 at z ¼ 0 (no drag at the gas–liquid interface), (3-88) is readily integrated to give a parabolic velocity profile: uy ¼ rgd2 2m 1 À z d   2 ! ð3-89Þ Liquid film element Bulk flow Gas Diffusion of A Liquid z = δ z z +Δz y +Δy z = 0, y = 0 y y z uy {z} cAi (in liquid) cA {z} Figure 3.12 Mass transfer from a gas into a falling, laminar liquid film. 106 Chapter 3 Mass Transfer and Diffusion

23. The maximum liquid velocity occurs at z ¼ 0, ðuy

    Þ max ¼ rgd2 2m ð3-90Þ The bulk-average velocity in the liquid film is  uy ¼ R d 0 uy dz d ¼ rgd2 3m ð3-91Þ Thus, with no entrance effects, the film thickness for fully developed flow is independent of location y and is d ¼ 3 uym rg   1=2 ¼ 3mG r2g   1=3 ð3-92Þ where G ¼ liquid film flow rate per unit width of film, W. For film flow, the Reynolds number, which is the ratio of the iner- tial force to the viscous force, is NRe ¼ 4rH  uyr m ¼ 4d uyr m ¼ 4G m ð3-93Þ where rH ¼ hydraulic radius ¼ (flow cross section)=(wetted perimeter) ¼ (Wd)=W ¼ d and, by continuity, G ¼  uyrd. Grimley [32] found that for NRe < 8 to 25, depending on surface tension and viscosity, flow in the film is laminar and the interface between the liquid film and gas is flat. The value of 25 is obtained with water. For 8 to 25 < NRe < 1,200, the flow is still laminar, but ripples may appear at the interface unless suppressed by the addition of wetting agents. For a flat interface and a low rate of mass transfer of A, Eqs. (3-88) to (3-93) hold, and the film velocity profile is given by (3-89). Consider a mole balance on A for an incre- mental volume of liquid film of constant density, as shown in Figure 3.12. Neglect bulk flow in the z-direction and axial diffusion in the y-direction. Thus, mass transfer of A from the gas into the liquid occurs only by molecular diffusion in the z-direction. Then, at steady state, neglecting accumula- tion or depletion of A in the incremental volume (quasi- steady-state assumption), ÀDAB ðDyÞðDxÞ qcA qz   z þ uy cA jy ðDzÞðDxÞ ¼ ÀDAB ðDyÞðDxÞ qcA qz   zþDz þ uy cA jyþDy ðDzÞðDxÞ ð3-94Þ Rearranging and simplifying (3-94), uy cA jyþDy À uy cA jy Dy ! ¼ DAB ðqcA =qzÞ zþDz À ðqcA =qzÞ z Dz ! ð3-95Þ which, in the limit, as Dz ! 0 and Dy ! 0, becomes uy qcA qy ¼ DAB q2cA qz2 ð3-96Þ Substituting the velocity profile of (3-89) into (3-96), rgd2 2m 1 À z d   2 ! qcA qy ¼ DAB q2cA qz2 ð3-97Þ This PDE was solved by Johnstone and Pigford [33] and Olbrich and Wild [34] for the following boundary conditions, where the initial concentration of A in the liquid film is cAo : cA ¼ cAi at z ¼ 0 for y > 0 cA ¼ cAo at y ¼ 0 for 0 < z < d qcA =qz ¼ 0 at z ¼ d for 0 < y < L where L ¼ height of the vertical surface. The solution of Olbrich and Wild is in the form of an infinite series, giving cA as a function of z and y. Of greater interest, however, is the average concentration of A in the film at the bottom of the wall, where y ¼ L, which, by integration, is  cAy ¼ 1  uyd Z d 0 uy cAy dz ð3-98Þ For the condition y ¼ L, the result is cAi À  cAL cAi À cAo ¼ 0:7857eÀ5:1213h þ 0:09726eÀ39:661h þ 0:036093eÀ106:25h þ Á Á Á ð3-99Þ where h ¼ 2DAB L 3d2 uy ¼ 8=3 NRe NSc ðd=LÞ ¼ 8=3 ðd=LÞNPeM ð3-100Þ NSc ¼ Schmidt number ¼ m rDAB ¼ momentum diffusivity; m=r mass diffusivity; DAB ð3-101Þ NPeM ¼ NRe NSc ¼ Peclet number for mass transfer ¼ 4d uy DAB ð3-102Þ The Schmidt number is analogous to the Prandtl number, used in heat transfer: NPr ¼ CPm k ¼ ðm=rÞ ðk=rCP Þ ¼ momentum diffusivity thermal diffusivity The Peclet number for mass transfer is analogous to the Peclet number for heat transfer: NPeH ¼ NRe NPr ¼ 4d uy CP r k Both are ratios of convective to molecular transport. The total rate of absorption of A from the gas into the liq- uid film for height L and width W is nA ¼  uydWð cAL À cAo Þ ð3-103Þ §3.4.2 Mass-Transfer Coefficients Mass-transfer problems involving flowing fluids are often solved using mass-transfer coefficients, which are analogous to heat-transfer coefficients. For the latter, Newton’s law of §3.4 Mass Transfer in Laminar Flow 107

24. cooling defines a heat-transfer coefficient, h: Q ¼ hADT ð3-104Þ

    where Q ¼ rate of heat transfer, A ¼ area for heat transfer (nor- mal to the direction of heat transfer), and DT ¼ temperature- driving force. For mass transfer, a composition-driving force replaces DT. Because composition can be expressed in a number of ways, different mass-transfer coefficients result. If concentra- tion is used, DcA is selected as the driving force and nA ¼ kc ADcA ð3-105Þ which defines a mass-transfer coefficient, kc, in mol/time- area-driving force, for a concentration driving force. Unfortunately, no name is in general use for (3-105). For the falling laminar film, DcA ¼ cAi À  cA, where  cA is the bulk average concentration of A in the film, which varies with vertical location, y, because even though cAi is indepen- dent of y, the average film concentration of A increases with y. A theoretical expression for kc in terms of diffusivity is formed by equating (3-105) to Fick’s first law at the gas– liquid interface: kc AðcAj À  cA Þ ¼ ÀDAB A qcA qz   z¼0 ð3-106Þ Although this is the most widely used approach for defin- ing a mass-transfer coefficient, for a falling film it fails because ðqcA =qzÞ at z ¼ 0 is not defined. Therefore, another approach is used. For an incremental height, nA ¼  uydW d cA ¼ kc ðcA? À  cA ÞW dy ð3-107Þ This defines a local value of kc, which varies with distance y because  cA varies with y. An average value of kc, over height L, can be defined by separating variables and integrat- ing (3-107): kcavg ¼ RL 0 kc dy L ¼  uyd RcAL cAo ½d cA =ðcAi À  cA ފ L ¼  uyd L ln cAi À cAo cAi À  cAL ð3-108Þ The argument of the natural logarithm in (3-108) is ob- tained from the reciprocal of (3-99). For values of h in (3- 100) greater than 0.1, only the first term in (3-99) is signifi- cant (error is less than 0.5%). In that case, kcavg ¼  uyd L ln e5:1213h 0:7857 ð3-109Þ Since ln ex ¼ x, kcavg ¼  uyd L ð0:241 þ 5:1213hÞ ð3-110Þ In the limit for large h, using (3-100) and (3-102), (3-110) becomes kcavg ¼ 3:414 DAB d ð3-111Þ As suggested by the Nusselt number, NNu ¼ hd=k for heat transfer, where d is a characteristic length, a Sherwood number for mass transfer is defined for a falling film as NShavg ¼ kcavg d DAB ð3-112Þ From (3-111), NShavg ¼ 3:414, which is the smallest value the Sherwood number can have for a falling liquid film. The average mass-transfer flux of A is NAavg ¼ nAavg A ¼ kcavg ðcAi À  cA Þ mean ð3-113Þ For h < 0.001 in (3-100), when the liquid-film flow regime is still laminar without ripples, the time of contact of gas with liquid is short and mass transfer is confined to the vicinity of the interface. Thus, the film acts as if it were infi- nite in thickness. In this limiting case, the downward velocity of the liquid film in the region of mass transfer is uy max , and (3-96) becomes uy max qcA qy ¼ DAB q2cA qz2 ð3-114Þ Since from (3-90) and (3-91) uy max ¼ 3uy =2, (3-114) becomes qcA qy ¼ 2DAB 3 uy   q2cA qz2 ð3-115Þ where the boundary conditions are cA ¼ cAo for z > 0 and y > 0 cA ¼ cAi for z ¼ 0 and y > 0 cA ¼ cAi for large z and y > 0 Equation (3-115) and the boundary conditions are equivalent to the case of the semi-infinite medium in Figure 3.6. By analogy to (3-68), (3-75), and (3-76), the solution is E ¼ 1 À u ¼ cAi À cA cAi À cAo ¼ erf z 2 ffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi 2DAB y=3 uy p ! ð3-116Þ Assuming that the driving force for mass transfer in the film is cAi À cA0 , Fick’s first law can be used at the gas–liquid interface to define a mass-transfer coefficient: NA ¼ ÀDAB qcA qz     z¼0 ¼ kc ðcAi À cAo Þ ð3-117Þ To obtain the gradient of cA at z ¼ 0 from (3-116), note that the error function is defined as erf z ¼ 2 ffiffiffiffi p p Z z 0 eÀt2 dt ð3-118Þ Combining (3-118) with (3-116) and applying the Leibnitz differentiation rule, qcA qz     z¼0 ¼ ÀðcAi À cAo Þ ffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi 3 uy 2pDAB y s ð3-119Þ Substituting (3-119) into (3-117) and introducing the Peclet number for mass transfer from (3-102), the local mass- 108 Chapter 3 Mass Transfer and Diffusion

25. transfer coefficient as a function of distance down from the

    top of the wall is obtained: kc ¼ ffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi 3D2 AB NPeM 8pyd s ¼ ffiffiffiffiffiffiffiffiffiffiffiffiffiffi 3DAB G 2pydr s ð3-120Þ The average value of kc over the film height, L, is obtained by integrating (3-120) with respect to y, giving kcavg ¼ ffiffiffiffiffiffiffiffiffiffiffiffiffiffi 6DAB G pdrL s ¼ ffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi 3D2 AB 2pdL NPeM s ð3-121Þ Combining (3-121) with (3-112) and (3-102), NShavg ¼ ffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi 3d 2pL NPeM r ¼ ffiffiffiffiffiffiffi 4 ph s ð3-122Þ where, by (3-108), the proper mean concentration driving force to use with kcavg is the log mean. Thus, ðcAi À  cA Þ mean ¼ ðcAi À  cA Þ LM ¼ ðcAi À cAo Þ À ðcAi À cAL Þ ln½ðcAi À cAo Þ=ðcAi À  cAL ފ ð3-123Þ When ripples are present, values of kcavg and NShavg are con- siderably larger than predicted by the above equations. The above development shows that asymptotic, closed- form solutions are obtained with relative ease for large and small values of h, as defined by (3-100). These limits, in terms of the average Sherwood number, are shown in Figure 3.13. The general solution for intermediate values of h is not available in closed form. Similar limiting solutions for large and small values of dimensionless groups have been obtained for a large variety of transport and kinetic phenomena (Churchill [35]). Often, the two limiting cases can be patched together to provide an estimate of the intermediate solution, if an intermediate value is available from experiment or the general numerical solution. The procedure is discussed by Churchill and Usagi [36]. The general solution of Emmert and Pigford [37] to the falling, laminar liquid film problem is included in Figure 3.13. EXAMPLE 3.13 Absorption of CO2 into a Falling Water Film. Water (B) at 25C, in contact with CO2 (A) at 1 atm, flows as a film down a wall 1 m wide and 3 m high at a Reynolds number of 25. Estimate the rate of absorption of CO2 into water in kmol/s: DAB ¼ 1:96  10À5cm2/s; r ¼ 1:0 g/cm3; mL ¼ 0:89 cP ¼ 0:00089 kg/m-s Solubility of CO2 at 1 atm and 25C ¼ 3.4  10À5 mol/cm3. Solution From (3-93), G ¼ NRe m 4 ¼ 25ð0:89Þð0:001Þ 4 ¼ 0:00556 kg m-s From (3-101), NSc ¼ m rDAB ¼ ð0:89Þð0:001Þ ð1:0Þð1;000Þð1:96  10À5Þð10À4Þ ¼ 454 From (3-92), d ¼ 3ð0:89Þð0:001Þð0:00556Þ 1:02ð1:000Þ2ð9:807Þ " # 1=3 ¼ 1:15  10À4 m From (3-90) and (3-91),  uy ¼ ð2=3Þuy max . Therefore,  uy ¼ 2 3 ð1:0Þð1;000Þð9:807Þð1:15  10À4Þ2 2ð0:89Þð0:001Þ " # ¼ 0:0486 m/s From (3-100), h ¼ 8=3 ð25Þð454Þ½ð1:15  10À4Þ=3Š ¼ 6:13 Therefore, (3-111) applies, giving kcavg ¼ 3:41ð1:96  10À5Þð10À4Þ 1:15  10À4 ¼ 5:81  10À5 m/s General solution Short residence-time solution Eq. (3-122) Long residence-time solution Eq. (3-111) 100 10 1 0.001 Sherwood number 8/3 ( /L)NPeM = η δ 0.1 0.01 1 10 Figure 3.13 Limiting and general solutions for mass transfer to a falling, laminar liquid film. §3.4 Mass Transfer in Laminar Flow 109

26. To obtain the rate of absorption,  cAL is determined.

    From (3-103) and (3-113), nA ¼  uydWð cAL À cAo Þ ¼ kcavg A ð cAL À cAo Þ ln½ðcAi À cAo Þ=ðcAi À cAL ފ Thus, ln cAi À cAo cAi À  cAL   ¼ kcavg A  uydW Solving for  cAL ,  cAL ¼ cAi À ðcAi À cAo Þ exp À kcavg A  uydW   L ¼ 3 m; W ¼ 1 m; A ¼ WL ¼ ð1Þð3Þ ¼ 3 m2 cAo ¼ 0; cAi ¼ 3:4  10À5mol/cm3 ¼ 3:4  10À2 kmol/m3  cAL ¼ 3:4  10À2 1 À exp À ð5:81  10À5Þð3Þ ð0:0486Þð1:15  10À4Þð1Þ ! & ' ¼ 3:4  10À2 kmol/m3 Thus, the exiting liquid film is saturated with CO2 , which implies equilibrium at the gas–liquid interface. From (3-103), nA ¼ 0:0486ð1:15  10À4Þð3:4  10À2Þ ¼ 1:9  10À7 kmol/s §3.4.3 Molecular Diffusion to a Fluid Flowing Across a Flat Plate—The Boundary Layer Concept Consider the flow of fluid (B) over a thin, horizontal, flat plate, as shown in Figure 3.14. Some possibilities for mass transfer of species A into B are: (1) the plate consists of ma- terial A, which is slightly soluble in B; (2) A is in the pores of an inert solid plate from which it evaporates or dissolves into B; and (3) the plate is a dense polymeric membrane through which A can diffuse and pass into fluid B. Let the fluid veloc- ity profile upstream of the plate be uniform at a free-system velocity of uo . As the fluid passes over the plate, the velocity ux in the direction x of flow is reduced to zero at the wall, which establishes a velocity profile due to drag. At a certain distance z that is normal to and upward out from the plate surface, the fluid velocity is 99% of uo . This distance, which increases with increasing distance x from the leading edge of the plate, is defined as the velocity boundary-layer thickness, d. Essentially all flow retardation is assumed to occur in the boundary layer, as first suggested by Prandtl [38]. The buildup of this layer, the velocity profile, and the drag force can be determined for laminar flow by solving the Navier– Stokes equations. For a Newtonian fluid of constant density and viscosity, with no pressure gradients in the x- or y-directions, these equations for the boundary layer are qux qx þ quz qz ¼ 0 ð3-124Þ ux qux qx þ uz qux qz ¼ m r q2ux qz2   ð3-125Þ The boundary conditions are ux ¼ uo at x ¼ 0 for z > 0; ux ¼ 0 at z ¼ 0 for x > 0 ux ¼ uo at z ¼ 1 for x > 0; uz ¼ 0 at z ¼ 0 for x > 0 A solution of (3-124) and (3-125) was first obtained by Bla- sius [39], as described by Schlichting [40]. The result in terms of a local friction factor, fx; a local shear stress at the wall, twx ; and a local drag coefficient at the wall, CDx , is CDx 2 ¼ fx 2 ¼ twx ru2 o ¼ 0:322 N0:5 Rex ð3-126Þ where NRex ¼ xuo r m ð3-127Þ The drag is greatest at the leading edge of the plate, where the Reynolds number is smallest. Values of the drag co- efficient obtained by integrating (3-126) from x ¼ 0 to L are CDavg 2 ¼ f avg 2 ¼ 0:664 ðNReL Þ0:5 ð3-128Þ The thickness of the velocity boundary layer increases with distance along the plate: d x ¼ 4:96 N0:5 Rex ð3-129Þ A reasonably accurate expression for a velocity profile was obtained by Pohlhausen [41], who assumed the empirical form of the velocity in the boundary layer to be ux ¼ C1 z þ C2 z3. If the boundary conditions ux ¼ 0 at z ¼ 0; ux ¼ uo at z ¼ d; qux =qz ¼ 0 at z ¼ d are applied to evaluate C1 and C2 , the result is ux uo ¼ 1:5 z d   À 0:5 z d   3 ð3-130Þ This solution is valid only for a laminar boundary layer, which by experiment persists up to NRex ¼ 5  105. When mass transfer of A from the surface of the plate into the boundary layer occurs, a species continuity equation applies: ux qcA qx þ uz qcA qz ¼ DAB q2cA qx2   ð3-131Þ If mass transfer begins at the leading edge of the plate and the concentration in the fluid at the solid–fluid interface is Velocity boundary layer Free stream Flat plate ux ux uo uo x z ux uo uo x δ Figure 3.14 Laminar boundary layer for flow across a flat plate. 110 Chapter 3 Mass Transfer and Diffusion

27. maintained constant, the additional boundary conditions are cA ¼ cAo

    at x ¼ 0 for z > 0; cA ¼ cAi at z ¼ 0 for x > 0; and cA ¼ cAo at z ¼ 1 for x > 0 If the rate of mass transfer is low, the velocity profiles are undisturbed. The analogous heat-transfer problem was first solved by Pohlhausen [42] for NPr > 0.5, as described by Schlichting [40]. The analogous result for mass transfer is NShx NRex N1=3 Sc ¼ 0:332 N0:5 Rex ð3-132Þ where NShx ¼ xkcx DAB ð3-133Þ and the driving force for mass transfer is cAi À cAo . The concentration boundary layer, where essentially all of the resistance to mass transfer resides, is defined by cAi À cA cAi À cAo ¼ 0:99 ð3-134Þ and the ratio of the concentration boundary-layer thickness, dc, to the velocity boundary thickness, d, is dc =d ¼ 1=N1=3 Sc ð3-135Þ Thus, for a liquid boundary layer where NSc > 1, the con- centration boundary layer builds up more slowly than the ve- locity boundary layer. For a gas boundary layer where NSc % 1, the two boundary layers build up at about the same rate. By analogy to (3-130), the concentration profile is cAi À cA cAi À cAo ¼ 1:5 z dc   À 0:5 z dc   3 ð3-136Þ Equation (3-132) gives the local Sherwood number. If this expression is integrated over the length of the plate, L, the average Sherwood number is found to be NShavg ¼ 0:664 N1=2 ReL N1=3 Sc ð3-137Þ where NShavg ¼ Lkcavg DAB ð3-138Þ EXAMPLE 3.14 Sublimation of Naphthalene from a Flat Plate. Air at 100C, 1 atm, and a free-stream velocity of 5 m/s flows over a 3-m-long, horizontal, thin, flat plate of naphthalene, causing it to sublime. Determine the: (a) length over which a laminar boundary layer persists, (b) rate of mass transfer over that length, and (c) thicknesses of the velocity and concentration boundary layers at the point of transition of the boundary layer to turbulent flow. The physical properties are: vapor pressure of naphthalene ¼ 10 torr; viscosity of air ¼ 0.0215 cP; molar density of air ¼ 0.0327 kmol/m3; and diffusivity of naphthalene in air ¼ 0.94  10À5 m2/s. Solution (a) NRex ¼ 5  105 for transition to turbulent flow. From (3-127), x ¼ L ¼ mNRex uo r ¼ ½ð0:0215Þð0:001ފð5  105Þ ð5Þ½ð0:0327Þð29ފ ¼ 2:27 m at which transition to turbulent flow begins. (b) cAo ¼ 0; cAi ¼ 10ð0:0327Þ 760 ¼ 4:3  10À4 kmol/m3. From (3-101), NSc ¼ m rDAB ¼ ½ð0:0215Þð0:001ފ ½ð0:0327Þð29ފð0:94  10À5Þ ¼ 2:41 From (3-137), NShavg ¼ 0:664ð5  105Þ1=2ð2:41Þ1=3 ¼ 630 From (3-138), kcavg ¼ 630ð0:94  10À5Þ 2:27 ¼ 2:61  10À3m/s For a width of 1 m, A ¼ 2.27 m2, nA ¼ kcavg AðcAi À cAo Þ ¼ 2:61  10À3ð2:27Þð4:3  10À4Þ ¼ 2:55  10À6kmol/s (c) From (3-129), at x ¼ L ¼ 2.27 m, d ¼ 3:46ð2:27Þ ð5  105Þ0:5 ¼ 0:0111 m From (3-135), dc ¼ 0:0111 ð2:41Þ1=3 ¼ 0:0083 m §3.4.4 Molecular Diffusion from the Inside Surface of a Circular Tube to a Flowing Fluid—The Fully Developed Flow Concept Figure 3.15 shows the development of a laminar velocity boundary layer when a fluid flows from a vessel into a straight, circular tube. At the entrance, a, the velocity profile is flat. A velocity boundary layer then begins to build up, as shown at b, c, and d in Figure 3.15. The central core outside the boundary layer has a flat velocity profile where the flow is accelerated over the entrance velocity. Finally, at plane e, the boundary layer fills the tube. Now the flow is fully developed. The distance from plane a to plane e is the entry region. The entry length Le is the distance from the entrance to the point at which the centerline velocity is 99% of fully devel- oped flow. From Langhaar [43], Le =D ¼ 0:0575 NRe ð3-139Þ For fully developed laminar flow in a tube, by experiment the Reynolds number, NRe ¼ D uxr=m, where  ux is the flow-aver- age velocity in the axial direction, x, and D is the inside di- ameter of the tube, must be less than 2,100. Then the equation of motion in the axial direction is m r q qr r qux qr   À dP qx ¼ 0 ð3-140Þ §3.4 Mass Transfer in Laminar Flow 111

28. with boundary conditions: r ¼ 0 ðaxis of the tubeÞ;

    qux =qr ¼ 0 and r ¼ rw ðtube wallÞ; ux ¼ 0 Equation (3-140) was integrated by Hagen in 1839 and Pois- euille in 1841. The resulting equation for the velocity profile, in terms of the flow-average velocity, is ux ¼ 2 ux 1 À r rw   2 " # ð3-141Þ or, in terms of the maximum velocity at the tube axis, ux ¼ uxmax 1 À r rw   2 " # ð3-142Þ According to (3-142), the velocity profile is parabolic. The shear stress, pressure drop, and Fanning friction fac- tor are obtained from solutions to (3-140): tw ¼ Àm qux qr      r¼rw ¼ 4m ux rw ð3-143Þ À dP dx ¼ 32m ux D2 ¼ 2fr u2 x D ð3-144Þ with f ¼ 16 NRe ð3-145Þ At the upper limit of laminar flow, NRe ¼ 2,100, and Le =D ¼ 121, but at NRe ¼ 100, Le =D is only 5.75. In the entry region, the friction factor is considerably higher than the fully devel- oped flow value given by (3-145). At x ¼ 0, f is infinity, but it decreases exponentially with x, approaching the fully devel- oped flow value at Le. For example, for NRe ¼ 1,000, (3-145) gives f ¼ 0.016, with Le =D ¼ 57.5. From x ¼ 0 to x=D ¼ 5.35, the average friction factor from Langhaar is 0.0487, which is three times the fully developed value. In 1885, Graetz [44] obtained a solution to the problem of convective heat transfer between the wall of a circular tube, at a constant temperature, and a fluid flowing through the tube in fully developed laminar flow. Assuming constant properties and negligible conduction in the axial direction, the energy equation, after substituting (3-141) for ux, is 2 ux 1 À r rw   2 " # qT qx ¼ k rCp 1 r q qr r qT qr   ! ð3-146Þ with boundary conditions: x ¼ 0 ðwhere heat transfer beginsÞ; T ¼ T0 ; for all r x > 0; r ¼ rw ; T ¼ Ti and x > 0; r ¼ 0; qT=qr ¼ 0 The analogous species continuity equation for mass trans- fer, neglecting bulk flow in the radial direction and axial dif- fusion, is 2 ux 1 À r rw   2 " # qcA qx ¼ DAB 1 r q qr r qcA qr   ! ð3-147Þ with analogous boundary conditions. The Graetz solution of (3-147) for the temperature or con- centration profile is an infinite series that can be obtained from (3-146) by separation of variables using the method of Frobenius. A detailed solution is given by Sellars, Tribus, and Klein [45]. The concentration profile yields expressions for the mass-transfer coefficient and the Sherwood number. For large x, the concentration profile is fully developed and the local Sherwood number, NShx , approaches a limiting value of 3.656. When x is small, such that the concentration boundary layer is very thin and confined to a region where the fully developed velocity profile is linear, the local Sherwood num- ber is obtained from the classic Leveque [46] solution, pre- sented by Knudsen and Katz [47]: NShx ¼ kcx D DAB ¼ 1:077 NPeM ðx=DÞ ! 1=3 ð3-148Þ where NPeM ¼ D ux DAB ð3-149Þ The limiting solutions, together with the general Graetz so- lution, are shown in Figure 3.16, where NShx ¼ 3:656 is valid for NPeM =ðx=DÞ < 4 and (3-148) is valid for NPeM =ðx=DÞ > 100. These solutions can be patched together if a point from the general solution is available at the intersection in a manner like that discussed in §3.4.2. Where mass transfer occurs, an average Sherwood number is derived by integrating the general expression for the local Entrance velocity = ux Entrance Thickness of boundary layer Edge of boundary layer Fully developed tube flow a b x c d e Figure 3.15 Buildup of a laminar velocity boundary layer for flow in a circular tube. 112 Chapter 3 Mass Transfer and Diffusion

29. Sherwood number. An empirical representation for that aver- age, proposed

    by Hausen [48], is NShavg ¼ 3:66 þ 0:0668½NPeM =ðx=Dފ 1 þ 0:04½NPeM =ðx=Dފ2=3 ð3-150Þ which is based on a log-mean concentration driving force. EXAMPLE 3.15 Mass Transfer of Benzoic Acid into Water Flowing in Laminar Motion Through a Tube. Linton and Sherwood [49] dissolved tubes of benzoic acid (A) into water (B) flowing in laminar flow through the tubes. Their data agreed with predictions based on the Graetz and Leveque equations. Consider a 5.23-cm-inside-diameter, 32-cm-long tube of benzoic acid, preceded by 400 cm of straight metal pipe wherein a fully developed velocity profile is established. Water enters at 25C at a velocity corresponding to a Reynolds number of 100. Based on property data at 25C, estimate the average concentration of benzoic acid leaving the tube before a significant increase in the inside diam- eter of the benzoic acid tube occurs because of dissolution. The properties are: solubility of benzoic acid in water ¼ 0.0034 g/cm3; viscosity of water ¼ 0.89 cP ¼ 0.0089 g/cm-s; and diffusivity of benzoic acid in water at infinite dilution ¼ 9.18  10À6 cm2/s. Solution NSc ¼ 0:0089 ð1:0Þð9:18  10À6Þ ¼ 970 NRe ¼ D uxr m ¼ 100 from which  ux ¼ ð100Þð0:0089Þ ð5:23Þð1:0Þ ¼ 0:170 cm/s From (3-149), NPeM ¼ ð5:23Þð0:170Þ 9:18  10À6 ¼ 9:69  104 x D ¼ 32 5:23 ¼ 6:12 NPeM ðx=DÞ ¼ 9:69  104 6:12 ¼ 1:58  104 From (3-150), NShavg ¼ 3:66 þ 0:0668ð1:58  104Þ 1 þ 0:04ð1:58  104Þ2=3 ¼ 44 kcavg ¼ NShavg DAB D   ¼ 44 ð9:18  10À6Þ 5:23 ¼ 7:7  10À5cm/s Using a log mean driving force, nA ¼  ux Sð cAx À cAo Þ ¼ kcavg A ½ðcAi À cAo Þ À ðcAi À  cAx ފ ln½ðcAi À cAo Þ=ðcAi À  cAx ފ where S is the cross-sectional area for flow. Simplifying, ln cAi À cAo cAi À  cAx   ¼ kcavg A  ux S cAo ¼ 0 and cAi ¼ 0:0034 g/cm3 S ¼ pD2 4 ¼ ð3:14Þð5:23Þ2 4 ¼ 21:5 cm2 and A ¼ pDx ¼ ð3:14Þð5:23Þð32Þ ¼ 526 cm2 ln 0:0034 0:0034 À  cAx   ¼ ð7:7  10À5Þð526Þ ð0:170Þð21:5Þ ¼ 0:0111  cAx ¼ 0:0034 À 0:0034 e0:0111 ¼ 0:000038 g/cm3 Thus, the concentration of benzoic acid in the water leaving the cast tube is far from saturation. §3.5 MASS TRANSFER IN TURBULENT FLOW The two previous sections described mass transfer in stagnant media (§3.3) and laminar flow (§3.4), where in (3-1), only two mechanisms needed to be considered: molecular diffu- sion and bulk flow, with the latter often ignored. For both cases, rates of mass transfer can be calculated theoretically using Fick’s law of diffusion. In the chemical industry, turbu- lent flow is more common because it includes eddy diffusion, which results in much higher heat and mass-transfer rates, and thus, requires smaller equipment. Lacking a fundamental theory for eddy diffusion, estimates of mass-transfer rates rely on empirical correlations developed from experimental Solution for fully developed concentration profile General solution Leveque solution 100 10 1 1 10 Sherwood number NPeM /(x /D) 100 1000 Figure 3.16 Limiting and general solutions for mass transfer to a fluid in laminar flow in a straight, circular tube. §3.5 Mass Transfer in Turbulent Flow 113

30. data. These correlations are comprised of the same dimen- sionless

    groups of §3.4 and use analogies with heat and mo- mentum transfer. For reference as this section is presented, the most useful dimensionless groups for fluid mechanics, heat transfer, and mass transfer are listed in Table 3.13. Note that most of the dimensionless groups used in empirical equations for mass transfer are analogous to dimensionless groups used in heat transfer. The Reynolds number from fluid mechanics is used widely in empirical equations of heat and mass transfer. As shown by a famous dye experiment conducted by Osborne Reynolds [50] in 1883, a fluid in laminar flow moves parallel to the solid boundaries in streamline patterns. Every fluid particle moves with the same velocity along a streamline, and there are no normal-velocity components. For a Newtonian fluid in laminar flow, momentum, heat, and mass transfer are by molecular transport, governed by New- ton’s law of viscosity, Fourier’s law of heat conduction, and Fick’s law of molecular diffusion, as described in the previ- ous section. In turbulent flow, where transport processes are orders of magnitude higher than in laminar flow, streamlines no longer exist, except near a wall, and eddies of fluid, which are large compared to the mean free path of the molecules in the fluid, mix with each other by moving from one region to another in fluctuating motion. This eddy mixing by velocity fluctuations Table 3.13 Some Useful Dimensionless Groups Name Formula Meaning Analogy Fluid Mechanics Drag Coefficient CD ¼ 2FD Au2r Drag force Projected area  Velocity head Fanning Friction Factor f ¼ DP L D 2 u2r Pipe wall shear stress Velocity head Froude Number NFr ¼  u2 gL Inertial force Gravitational force Reynolds Number NRe ¼ L ur m ¼ L u v ¼ LG m Inertial force Viscous force Weber Number NWe ¼  u2rL s Inertial force Surface-tension force Heat Transfer j-Factor for Heat Transfer j H ¼ NStH ðNPr Þ2=3 jM Nusselt Number NNu ¼ hL k Convective heat transfer Conductive heat transfer NSh Peclet Number for Heat Transfer NPeH ¼ NRe NPr ¼ L urCp k Bulk transfer of heat Conductive heat transfer NPeM Prandtl Number NPr ¼ Cpm k ¼ v a Momentum diffusivity Thermal diffusivity NSc Stanton Number for Heat Transfer NStH ¼ NNu NRe NPr ¼ h Cp G Heat transfer Thermal capacity NStM Mass Transfer j-Factor for Mass Transfer (analogous to the j-Factor for Heat Transfer) j M ¼ NStM ðNSc Þ2=3 jH Lewis Number NLe ¼ NSc NPr ¼ k rCp DAB ¼ a DAB Thermal diffusivity Mass diffusivity Peclet Number for Mass Transfer (analogous to the Peclet Number for Heat Transfer) NPeM ¼ NRe NSc ¼ L u DAB Bulk transfer of mass Molecular diffusion NPeH Schmidt Number (analogous to the Prandtl Number) NSc ¼ m rDAB ¼ v DAB Momentum diffusivity Mass diffusivity NPr Sherwood Number (analogous to the Nusselt Number) NSh ¼ kc L DAB Convective mass transfer Molecular diffusion NNu Stanton Number for Mass Transfer (analogous to the Stanton Number for Heat Transfer) NStM ¼ NSh NRe NSc ¼ kc  ur Mass transfer Mass capacity NStH L ¼ characteristic length, G ¼ mass velocity ¼  ur, Subscripts: M ¼ mass transfer H ¼ heat transfer 114 Chapter 3 Mass Transfer and Diffusion

31. occurs not only in the direction of flow but also

    in directions normal to flow, with the former referred to as axial transport but with the latter being of more interest. Momentum, heat, and mass transfer now occur by the two parallel mechanisms given in (3-1): (1) molecular diffusion, which is slow; and (2) turbulent or eddy diffusion, which is rapid except near a solid surface, where the flow velocity accompanying turbu- lence tends to zero. Superimposed on molecular and eddy diffusion is (3) mass transfer by bulk flow, which may or may not be significant. In 1877, Boussinesq [51] modified Newton’s law of vis- cosity to include a parallel eddy or turbulent viscosity, mt. Analogous expressions were developed for turbulent-flow heat and mass transfer. For flow in the x-direction and trans- port in the z-direction normal to flow, these expressions are written in flux form (in the absence of bulk flow in the z- direction) as: tzx ¼ Àðm þ mt Þ dux dz ð3-151Þ qz ¼ Àðk þ kt Þ dT dz ð3-152Þ NAz ¼ ÀðDAB þ Dt Þ dcA dz ð3-153Þ where the double subscript zx on the shear stress, t, stands for x-momentum in the z-direction. The molecular contribu- tions, m, k, and DAB , are properties of the fluid and depend on chemical composition, temperature, and pressure; the turbu- lent contributions, mt, kt, and Dt, depend on the mean fluid velocity in the flow direction and on position in the fluid with respect to the solid boundaries. In 1925, Prandtl [52] developed an expression for mt in terms of an eddy mixing length, l, which is a function of posi- tion and is a measure of the average distance that an eddy travels before it loses its identity and mingles with other eddies. The mixing length is analogous to the mean free path of gas molecules, which is the average distance a molecule travels before it collides with another molecule. By analogy, the same mixing length is valid for turbulent-flow heat trans- fer and mass transfer. To use this analogy, (3-151) to (3-153) are rewritten in diffusivity form: tzx r ¼ Àðv þ eM Þ dux dz ð3-154Þ qz Cpr ¼ Àða þ eH Þ dT dz ð3-155Þ NAz ¼ ÀðDAB þ eD Þ dcA dz ð3-156Þ where eM, eH, and eD are momentum, heat, and mass eddy diffusivities, respectively; v is the momentum diffusivity (kinematic viscosity, m=r); and a is the thermal diffusivity, k/rCP . As an approximation, the three eddy diffusivities may be assumed equal. This is valid for eH and eD, but data indi- cate that eM =eH ¼ eM/eD is sometimes less than 1.0 and as low as 0.5 for turbulence in a free jet. §3.5.1 Reynolds Analogy If (3-154) to (3-156) are applied at a solid boundary, they can be used to determine transport fluxes based on transport coef- ficients, with driving forces from the wall (or interface), i, at z ¼ 0, to the bulk fluid, designated with an overbar,: tzx  ux ¼ Àðv þ eM Þ dðrux = ux Þ dz     z¼0 ¼ fr 2  ux ð3-157Þ qz ¼ Àða þ eH Þ dðrCP TÞ dz     z¼0 ¼ hðTi À TÞ ð3-158Þ NAz ¼ ÀðDAB þ eD Þ dcA dz     z¼0 ¼ kc ðcA À  cA Þ ð3-159Þ To develop useful analogies, it is convenient to use dimen- sionless velocity, temperature, and solute concentration, defined by u ¼ ux  ux ¼ Ti À T Ti À T ¼ cAj À cA cAi À  cA ð3-160Þ If (3-160) is substituted into (3-157) to (3-159), qu qz     z¼0 ¼ f ux 2ðv þ eM Þ ¼ h rCP ða þ eH Þ ¼ kc ðDAB þ eD Þ ð3-161Þ which defines analogies among momentum, heat, and mass transfer. If the three eddy diffusivities are equal and molecu- lar diffusivities are everywhere negligible or equal, i.e., n ¼ a ¼ DAB , (3-161) simplifies to f 2 ¼ h rCP  ux ¼ kc  ux ð3-162Þ Equation (3-162) defines the Stanton number for heat transfer listed in Table 3.13, NStH ¼ h rCP  ux ¼ h GCP ð3-163Þ where G ¼ mass velocity ¼  uxr. The Stanton number for mass transfer is NStM ¼ kc  ux ¼ kcr G ð3-164Þ Equation (3-162) is referred to as the Reynolds analogy. Its development is significant, but its application for the estima- tion of heat- and mass-transfer coefficients from measure- ments of the Fanning friction factor for turbulent flow is valid only when NPr ¼ n=a ¼ NSc ¼ n=DAB ¼ 1. Thus, the Reynolds analogy has limited practical value and is rarely used. Reynolds postulated its existence in 1874 [53] and de- rived it in 1883 [50]. §3.5.2 Chilton–Colburn Analogy A widely used extension of the Reynolds analogy to Prandtl and Schmidt numbers other than 1 was devised in the 1930s §3.5 Mass Transfer in Turbulent Flow 115

32. by Colburn [54] for heat transfer and by Chilton and

    Colburn [55] for mass transfer. Using experimental data, they cor- rected the Reynolds analogy for differences in dimensionless velocity, temperature, and concentration distributions by incorporating the Prandtl number, NPr , and the Schmidt num- ber, NSc , into (3-162) to define empirically the following three j-factors included in Table 3.13. jM  f 2 ¼ jH  h GCP ðNPr Þ2=3 ¼ jD  kcr G ðNSc Þ2=3 ð3-165Þ Equation (3-165) is the Chilton–Colburn analogy or the Col- burn analogy for estimating transport coefficients for turbu- lent flow. For NPr ¼ NSc ¼ 1, (3-165) equals (3-162). From experimental studies, the j-factors depend on the ge- ometric configuration and the Reynolds number, NRe . Based on decades of experimental transport data, the following rep- resentative j-factor correlations for turbulent transport to or from smooth surfaces have evolved. Additional correlations are presented in later chapters. These correlations are reason- ably accurate for NPr and NSc in the range 0.5 to 10. 1. Flow through a straight, circular tube of inside diame- ter D: jM ¼ jH ¼ jD ¼ 0:023ðNRe ÞÀ0:2 ð3-166Þ for 10,000 < NRe ¼ DG=m < 1,000,000 2. Average transport coefficients for flow across a flat plate of length L: jM ¼ jH ¼ jD ¼ 0:037ðNRe ÞÀ0:2 ð3-167Þ for 5 Â 105< NRe ¼ Luo =m < 5 Â 108 3. Average transport coefficients for flow normal to a long, circular cylinder of diameter D, where the drag coefficient includes both form drag and skin friction, but only the skin friction contribution applies to the analogy: ðjM Þ skin friction ¼ jH ¼ jD ¼ 0:193ðNRe ÞÀ0:382 ð3-168Þ for 4,000 < NRe < 40,000 ðjM Þ skin friction ¼ jH ¼ jD ¼ 0:0266ðNRe ÞÀ0:195 ð3-169Þ for 40,000 < NRe < 250,000 with NRe ¼ DG m 4. Average transport coefficients for flow past a single sphere of diameter D: ðjM Þ skin friction ¼ jH ¼ jD ¼ 0:37ðNRe ÞÀ0:4 for 20 < NRe ¼ DG m < 100;000 ð3-170Þ 5. Average transport coefficients for flow through beds packed with spherical particles of uniform size DP: jH ¼ jD ¼ 1:17ðNRe ÞÀ0:415 for 10 < NRe ¼ DP G m < 2;500 ð3-171Þ The above correlations are plotted in Figure 3.17, where the curves are not widely separated but do not coincide because of necessary differences in Reynolds number definitions. When using the correlations in the presence of appreciable tempera- ture and/or composition differences, Chilton and Colburn recommend that NPr and NSc be evaluated at the average condi- tions from the surface to the bulk stream. §3.5.3 Other Analogies New theories have led to improvements of the Reynolds anal- ogy to give expressions for the Fanning friction factor and Stanton numbers for heat and mass transfer that are less empirical than the Chilton–Colburn analogy. The first major improvement was by Prandtl [56] in 1910, who divided the flow into two regions: (1) a thin laminar-flow sublayer of thickness d next to the wall boundary, where only molecular transport occurs; and (2) a turbulent region dominated by eddy transport, with eM ¼ eH ¼ eD. Further improvements to the Reynolds analogy were made by von Karman, Martinelli, and Deissler, as discussed in 1.000 0.100 0.010 0.001 1 10 100 1,000 10,000 100,000 1,000,000 Flat plate Tube flow Cylinder Sphere Packed bed 10,000,000 j-factor Reynolds number Figure 3.17 Chilton–Colburn j-factor correlations. 116 Chapter 3 Mass Transfer and Diffusion

33. detail by Knudsen and Katz [47]. The first two investigators

    inserted a buffer zone between the laminar sublayer and tur- bulent core. Deissler gradually reduced the eddy diffusivities as the wall was approached. Other advances were made by van Driest [64], who used a modified form of the Prandtl mixing length; Reichardt [65], who eliminated the zone con- cept by allowing the eddy diffusivities to decrease continu- ously from a maximum to zero at the wall; and Friend and Metzner [57], who obtained improved accuracy at Prandtl and Schmidt numbers to 3,000. Their results for flow through a circular tube are NStH ¼ f=2 1:20 þ 11:8 ffiffiffiffiffiffiffi f=2 p ðNPr À 1ÞðNPr ÞÀ1=3 ð3-172Þ NStM ¼ f=2 1:20 þ 11:8 ffiffiffiffiffiffiffi f=2 p ðNSc À 1ÞðNSc ÞÀ1=3 ð3-173Þ where the Fanning friction factor can be estimated over Rey- nolds numbers from 10,000 to 10,000,000 using the empiri- cal correlation of Drew, Koo, and McAdams [66], f ¼ 0:00140 þ 0:125ðNRe ÞÀ0:32 ð3-174Þ which fits the experimental data of Nikuradse [67] and is pre- ferred over (3-165) with (3-166), which is valid only to NRe ¼ 1,000,000. For two- and three-dimensional turbulent-flow problems, some success has been achieved with the k (kinetic energy of turbulence)–e (rate of dissipation) model of Laun- der and Spalding [68], which is widely used in computational fluid dynamics (CFD) computer programs. §3.5.4 Theoretical Analogy of Churchill and Zajic An alternative to (3-154) to (3-156) for developing equations for turbulent flow is to start with time-averaged equations of Newton, Fourier, and Fick. For example, consider a form of Newton’s law of viscosity for molecular and turbulent trans- port of momentum in parallel, where, in a turbulent-flow field in the axial x-direction, instantaneous velocity components ux and uz are ux ¼  ux þ u0 x uz ¼ u0 z The ‘‘overbarred’’ component is the time-averaged (mean) local velocity, and the primed component is the local fluctu- ating velocity that denotes instantaneous deviation from the local mean value. The mean velocity in the perpendicular z- direction is zero. The mean local velocity in the x-direction over a long period Q of time u is given by  ux ¼ 1 Q Z Q 0 ux du ¼ 1 Q Z Q 0 ð ux þ u0 x Þdu ð3-175Þ Time-averaged fluctuating components u0 x and u0 z are zero. The local instantaneous rate of momentum transfer by tur- bulence in the z-direction of x-direction turbulent momentum per unit area at constant density is ru0 z ð ux þ u0 x Þ ð3-176Þ The time-average of this turbulent momentum transfer is equal to the turbulent component of the shear stress, tzxt , tzxt ¼ r Q Z Q 0 u0 z ð ux þ u0 x Þdu ¼ r Q Z Q 0 u0 z ð ux Þdu þ Z Q 0 u0 z ðu0 x Þdu ! ð3-177Þ Because the time-average of the first term is zero, (3-177) reduces to tzxt ¼ rðu0 z u0 x Þ ð3-178Þ which is referred to as a Reynolds stress. Combining (3-178) with the molecular component of momentum transfer gives the following turbulent-flow form of Newton’s law of viscos- ity, where the second term on the right-hand side accounts for turbulence, tzx ¼ Àm dux dz þ rðu0 z u0 x Þ ð3-179Þ If (3-179) is compared to (3-151), it is seen that an alternative approach to turbulence is to develop a correlating equation for the Reynolds stress, ðu0 z u0 x Þ first introduced by Churchill and Chan [73], rather than an expression for turbulent viscos- ity mt. This stress is a complex function of position and rate of flow and has been correlated for fully developed turbulent flow in a straight, circular tube by Heng, Chan, and Churchill [69]. In generalized form, with tube radius a and y ¼ (a À z) representing the distance from the inside wall to the center of the tube, their equation is ðu0 z u0 x Þþþ ¼ 0:7 yþ 10   3 " #À8=7 þ exp À1 0:436yþ & '     0 @ À 1 0:436aþ 1 þ 6:95yþ aþ      À8=7 !À7=8 ð3-180Þ where ðu0 z u0 x Þþþ ¼ Àru0 z u0 x =t aþ ¼ aðtwrÞ1=2=m yþ ¼ yðtwrÞ1=2=m Equation (3-180) is an accurate representation of turbulent flow because it is based on experimental data and numerical simulations described by Churchill and Zajic [70] and Churchill [71]. From (3-142) and (3-143), the shear stress at the wall, tw, is related to the Fanning friction factor by f ¼ 2tw r u2 x ð3-181Þ where  ux is the flow-average velocity in the axial direction. Combining (3-179) with (3-181) and performing the required integrations, both numerically and analytically, leads to the following implicit equation for the Fanning friction factor as a function of the Reynolds number, NRe ¼ 2a uxr=m: §3.5 Mass Transfer in Turbulent Flow 117

34. 2 f   1=2 ¼ 3:2 À 227 2

    f   1=2 NRe 2 þ 2500 2 f   1=2 NRe 2 2 6 6 6 4 3 7 7 7 5 2 þ 1 0:436 ln NRe 2 2 f   1=2 2 6 6 6 4 3 7 7 7 5 ð3-182Þ This equation is in agreement with experimental data over a Reynolds number range of 4,000–3,000,000 and can be used up to a Reynolds number of 100,000,000. Table 3.14 presents a comparison of the Churchill–Zajic equation, (3-182), with (3-174) of Drew et al. and (3-166) of Chilton and Colburn. Equation (3-174) gives satisfactory agreement for Reynolds numbers from 10,000 to 10,000,000, while (3-166) is useful only for Reynolds numbers from 100,000 to 1,000,000. Churchill and Zajic [70] show that if the equation for the conservation of energy is time-averaged, a turbulent-flow form of Fourier’s law of conduction can be obtained with the fluctuation term ðu0 z T0Þ. Similar time-averaging leads to a tur- bulent-flow form of Fick’s law withðu0 z c0 A Þ. To extend (3- 180) and (3-182) to obtain an expression for the Nusselt num- ber for turbulent-flow convective heat transfer in a straight, circular tube, Churchill and Zajic employ an analogy that is free of empiricism but not exact. The result for Prandtl num- bers greater than 1 is NNu ¼ 1 NPrt NPr   1 NNu1 þ 1 À NPrt NPr   2=3 " # 1 NNu1 ð3-183Þ where, from Yu, Ozoe, and Churchill [72], NPrt ¼ turbulent Prandtl number ¼ 0:85 þ 0:015 NPr ð3-184Þ which replaces ðu0 z T0Þ, as introduced by Churchill [74], NNu1 ¼ Nusselt number forðNPr ¼ NPrt Þ ¼ NRe f 2   1 þ 145 2 f  À5=4 ð3-185Þ NNu1 ¼ Nusselt number forðNPr ¼ 1Þ ¼ 0:07343 NPr NPrt   1=3 NRe f 2   1=2 ð3-186Þ The accuracy of (3-183) is due to (3-185) and (3-186), which are known from theoretical considerations. Although (3-184) is somewhat uncertain, its effect on (3-183) is negligible. A comparison is made in Table 3.15 of the Churchill et al. correlation (3-183) with that of Friend and Metzner (3-172) and that of Chilton and Colburn (3-166), where, from Table 3.13, NNu ¼ NSt NRe NPr . In Table 3.15, at a Prandtl number of 1, which is typical of low-viscosity liquids and close to that of most gases, the Chilton–Colburn correlation is within 10% of the Churchill– Zajic equation for Reynolds numbers up to 1,000,000. Be- yond that, serious deviations occur (25% at NRe ¼ 10,000,000 Table 3.14 Comparison of Fanning Friction Factors for Fully Developed Turbulent Flow in a Smooth, Straight, Circular Tube NRe f, Drew et al. (3-174) f, Chilton–Colburn (3-166) f, Churchill–Zajic (3-182) 10,000 0.007960 0.007291 0.008087 100,000 0.004540 0.004600 0.004559 1,000,000 0.002903 0.002902 0.002998 10,000,000 0.002119 0.001831 0.002119 100,000,000 0.001744 0.001155 0.001573 Table 3.15 Comparison of Nusselt Numbers for Fully Developed Turbulent Flow in a Smooth, Straight, Circular Tube Prandtl number, NPr ¼ 1 NRe NNu , Friend–Metzner (3-172) NNu , Chilton–Colburn (3-166) NNu , Churchill–Zajic (3-183) 10,000 33.2 36.5 37.8 100,000 189 230 232 1,000,000 1210 1450 1580 10,000,000 8830 9160 11400 100,000,000 72700 57800 86000 Prandt number, NPr ¼ 1000 NRe NNu , Friend–Metzner (3-172) NNu , Chilton–Colburn (3-166) NNu , Churchill–Zajic (3-183) 10,000 527 365 491 100,000 3960 2300 3680 1,000,000 31500 14500 29800 10,000,000 267800 91600 249000 100,000,000 2420000 578000 2140000 118 Chapter 3 Mass Transfer and Diffusion

35. and almost 50% at NRe ¼ 100,000,000). Deviations of the

    Friend–Metzner correlation vary from 15% to 30% over the entire range of Reynolds numbers. At all Reynolds numbers, the Churchill–Zajic equation predicts higher Nusselt numbers and, therefore, higher heat-transfer coefficients. At a Prandtl number of 1,000, which is typical of high- viscosity liquids, the Friend–Metzner correlation is in fairly close agreement with the Churchill–Zajic equation. The Chil- ton–Colburn correlation deviates over the entire range of Reynolds numbers, predicting values ranging from 74 to 27% of those from the Churchill–Zajic equation as the Rey- nolds number increases. The Chilton–Colburn correlation should not be used at high Prandtl numbers for heat transfer or at high Schmidt numbers for mass transfer. The Churchill–Zajic equation for predicting the Nusselt number provides a power dependence on the Reynolds num- ber. This is in contrast to the typically cited constant expo- nent of 0.8 for the Chilton–Colburn correlation. For the Churchill–Zajic equation, at NPr ¼ 1, the exponent increases with Reynolds number from 0.79 to 0.88; at a Prandtl number of 1,000, the exponent increases from 0.87 to 0.93. Extension of the Churchill–Zajic equation to low Prandtl numbers typical of molten metals, and to other geometries is discussed by Churchill [71], who also considers the effect of boundary conditions (e.g., constant wall temperature and uni- form heat flux) at low-to-moderate Prandtl numbers. For calculation of convective mass-transfer coefficients, kc, for turbulent flow of gases and liquids in straight, smooth, circular tubes, it is recommended that the Churchill–Zajic equation be employed by applying the analogy between heat and mass transfer. Thus, as illustrated in the following exam- ple, in (3-183) to (3-186), using Table 3.13, the Sherwood number is substituted for the Nusselt number, and the Schmidt number is substituted for the Prandtl number. EXAMPLE 3.16 Analogies for Turbulent Transport. Linton and Sherwood [49] conducted experiments on the dissolving of tubes of cinnamic acid (A) into water (B) flowing turbulently through the tubes. In one run, with a 5.23-cm-i.d. tube, NRe ¼ 35,800, and NSc ¼ 1,450, they measured a Stanton number for mass transfer, NStM , of 0.0000351. Compare this experimental value with predictions by the Reynolds, Chilton–Colburn, and Friend–Metzner analogies and the Churchill–Zajic equation. Solution From either (3-174) or (3-182), the Fanning friction factor is 0.00576. Reynolds analogy. From (3-162), NStM ¼ f=2 ¼ 0:00576=2 ¼ 0:00288, which, as expected, is in very poor agreement with the experimental value because the effect of the large Schmidt number is ignored. Chilton–Colburn analogy. From (3-165), NStM ¼ f 2   =ðNSc Þ2=3 ¼ 0:00576 2   =ð1450Þ2=3 ¼ 0:0000225; which is 64% of the experimental value. Friend–Metzner analogy: From (3-173), NStM ¼ 0:0000350, which is almost identical to the experimental value. Churchill–Zajic equation. Using mass-transfer analogs, ð3-184Þgives NSct ¼ 0:850; ð3-185Þ gives NSh1 ¼ 94; ð3-186Þgives NSh1 ¼ 1686; and ð3-183Þ gives NSh ¼ 1680 From Table 3.13, NStM ¼ NSh NRe NSc ¼ 1680 ð35800Þð1450Þ ¼ 0:0000324; which is an acceptable 92% of the experimental value. §3.6 MODELS FOR MASS TRANSFER IN FLUIDS WITH A FLUID–FLUID INTERFACE The three previous sections considered mass transfer mainly between solids and fluids, where the interface was a smooth, solid surface. Applications occur in adsorption, drying, leaching, and membrane separations. Of importance in other separation operations is mass transfer across a fluid–fluid interface. Such interfaces exist in absorption, distillation, extraction, and stripping, where, in contrast to fluid–solid interfaces, turbulence may persist to the interface. The fol- lowing theoretical models have been developed to describe such phenomena in fluids with a fluid-to-fluid interface. There are many equations in this section and the following section, but few applications. However, use of these equa- tions to design equipment is found in many examples in: Chapter 6 on absorption and stripping; Chapter 7 on distilla- tion; and Chapter 8 on liquid–liquid extraction. §3.6.1 Film Theory A model for turbulent mass transfer to or from a fluid-phase boundary was suggested in 1904 by Nernst [58], who postu- lated that the resistance to mass transfer in a given turbulent fluid phase is in a thin, relatively stagnant region at the inter- face, called a film. This is similar to the laminar sublayer that forms when a fluid flows in the turbulent regime parallel to a flat plate. It is shown schematically in Figure 3.18a for a gas– liquid interface, where the gas is component A, which dif- fuses into non-volatile liquid B. Thus, a process of absorption of A into liquid B takes place, without vaporization of B, and there is no resistance to mass transfer of A in the gas phase, because it is pure A. At the interface, phase equilibrium is assumed, so the concentration of A at the interface, cAi , is related to the partial pressure of A at the interface, pA , by a solubility relation like Henry’s law, cAi ¼ HA p A . In the liquid film of thickness d, molecular diffusion occurs with a driving force of cAi À cAb , where cAb is the bulk-average concentra- tion of A in the liquid. Since the film is assumed to be very thin, all of the diffusing A is assumed to pass through the film and into the bulk liquid. Accordingly, integration of Fick’s first law, (3-3a), gives JA ¼ DAB d ðcAi À cAb Þ ¼ cDAB d ðxAi À xAb Þ ð3-187Þ §3.6 Models for Mass Transfer in Fluids with a Fluid–Fluid Interface 119

36. If the liquid phase is dilute in A, the bulk-flow

    effect can be neglected so that (3-187) applies to the total flux, and the concentration gradient is linear, as in Figure 3.18a. NA ¼ DAB d ðcAi À cAb Þ ¼ cDAB d ðxAi À cAb Þ ð3-188Þ If the bulk-flow effect is not negligible, then, from (3-31), NA ¼ cDAB d ln 1 À xAb 1 À xAi ! ¼ cDAB dð1 À xA Þ LM ðxAi À xAb Þ ð3-189Þ where ð1 À xA Þ LM ¼ xAi À xAb ln½ð1 À xAb Þ=ð1 À xAi ފ ¼ ðxB Þ LM ð3-190Þ In practice, the ratios DAB =d in (3-188) and DAB =[d (1 À xA )LM ] in (3-189) are replaced by empirical mass-transfer coef- ficients kc and k0 c, respectively, because the film thickness, d, which depends on the flow conditions, is unknown. The sub- script, c, on the mass-transfer coefficient refers to a concentra- tion driving force, and the prime superscript denotes that kc includes both diffusion mechanisms and the bulk-flow effect. The film theory, which is easy to understand and apply, is often criticized because it predicts that the rate of mass transfer is proportional to molecular diffusivity. This dependency is at odds with experimental data, which indicate a dependency of Dn, where n ranges from 0.5 to 0.75. However, if DAB =d is replaced with kc, which is then estimated from the Chilton– Colburn analogy (3-165), kc is proportional to D2=3 AB , which is in better agreement with experimental data. In effect, d is not a constant but depends on DAB (or NSc ). Regardless of whether the criticism is valid, the film theory continues to be widely used in design of mass-transfer separation equipment. EXAMPLE 3.17 Mass-Transfer Flux in a Packed Absorption Tower. SO2 is absorbed from air into water in a packed absorption tower. At a location in the tower, the mass-transfer flux is 0.0270 kmol SO2 /m2-h, and the liquid-phase mole fractions are 0.0025 and 0.0003, respectively, at the two-phase interface and in the bulk liq- uid. If the diffusivity of SO2 in water is 1.7  10À5 cm2/s, determine the mass-transfer coefficient, kc, and the corresponding film thick- ness, neglecting the bulk flow effect. Solution NSO2 ¼ 0:027ð1;000Þ ð3;600Þð100Þ2 ¼ 7:5  10À7 mol cm2-s For dilute conditions, the concentration of water is c ¼ 1 18:02 ¼ 5:55  10À2 mol/cm3 From (3-188), kc ¼ DAB d ¼ NA cðxAi À xAb Þ ¼ 7:5  10À7 5:55  10À2ð0:0025 À 0:0003Þ ¼ 6:14  10À3 cm/s Therefore, d ¼ DAB kc ¼ 1:7  10À5 6:14  10À3 ¼ 0:0028 cm which is small and typical of turbulent-flow processes. §3.6.2 Penetration Theory A more realistic mass-transfer model is provided by Higbie’s penetration theory [59], shown schematically in Figure 3.18b. The stagnant-film concept is replaced by Boussinesq eddies that: (1) move from the bulk liquid to the interface; (2) stay at the interface for a short, fixed period of time during which they remain static, allowing molecular diffusion to take place in a direction normal to the interface; and (3) leave the inter- face to mix with the bulk stream. When an eddy moves to the interface, it replaces a static eddy. Thus, eddies are alter- nately static and moving. Turbulence extends to the interface. In the penetration theory, unsteady-state diffusion takes place at the interface during the time the eddy is static. This process is governed by Fick’s second law, (3-68), with boundary conditions Interfacial region Gas Bulk liquid pA (a) (b) Gas pA z = O z = L δ Well-mixed bulk region at cAb cAi cAb cAi cAb Liquid film Figure 3.18 Theories for mass transfer from a fluid–fluid interface into a liquid: (a) film theory; (b) penetration and surface-renewal theories. 120 Chapter 3 Mass Transfer and Diffusion

37. cA ¼ cAb at t ¼ 0 for 0 z

    1; cA ¼ cAi at z ¼ 0 for t > 0; and cA ¼ cAb at z ¼ 1 for t > 0 These are the same boundary conditions as in unsteady-state diffusion in a semi-infinite medium. The solution is a re- arrangement of (3-75): cAi À cA cAi À cAb ¼ erf z 2 ffiffiffiffiffiffiffiffiffiffiffiffi DAB tc p   ð3-191Þ where tc ¼ ‘‘contact time’’ of the static eddy at the interface during one cycle. The corresponding average mass-transfer flux of A in the absence of bulk flow is given by the following form of (3-79): NA ¼ 2 ffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffi DAB ptc ðcAi À cAb Þ r ð3-192Þ or NA ¼ kc ðcAi À cAb Þ ð3-193Þ Thus, the penetration theory gives kc ¼ 2 ffiffiffiffiffiffiffiffiffi DAB ptc r ð3-194Þ which predicts that kc is proportional to the square root of the diffusivity, which is at the lower limit of experimental data. Penetration theory is most useful for bubble, droplet, or random-packing interfaces. For bubbles, the contact time, tc, of the liquid surrounding the bubble is approximated by the ratio of bubble diameter to its rise velocity. An air bubble of 0.4-cm diameter rises through water at a velocity of about 20 cm/s, making the estimated contact time 0.4=20 ¼ 0.02 s. For a liquid spray, where no circulation of liquid occurs inside the droplets, contact time is the total time it takes the droplets to fall through the gas. For a packed tower, where the liquid flows as a film over random packing, mixing is assumed to occur each time the liquid film passes from one piece of packing to another. Resulting contact times are about 1 s. In the absence of any estimate for contact time, the mass- transfer coefficient is sometimes correlated by an empirical expression consistent with the 0.5 exponent on DAB , as in (3-194), with the contact time replaced by a function of geometry and the liquid velocity, density, and viscosity. EXAMPLE 3.18 Contact Time for Penetration Theory. For the conditions of Example 3.17, estimate the contact time for Higbie’s penetration theory. Solution From Example 3.17, kc ¼ 6.14 Â 10À3 cm/s and DAB ¼ 1.7 Â 10À5 cm2/s. From a rearrangement of (3-194), tc ¼ 4DAB pk2 c ¼ 4ð1:7 Â 10À5Þ 3:14ð6:14 Â 10À3Þ2 ¼ 0:57 s §3.6.3 Surface-Renewal Theory The penetration theory is inadequate because the assumption of a constant contact time for all eddies that reach the sur- face is not reasonable, especially for stirred tanks, contactors with random packings, and bubble and spray columns where bubbles and droplets cover a range of sizes. In 1951, Danck- werts [60] suggested an improvement to the penetration the- ory that involves the replacement of constant eddy contact time with the assumption of a residence-time distribution, wherein the probability of an eddy at the surface being replaced by a fresh eddy is independent of the age of the sur- face eddy. Following Levenspiel’s [61] treatment of residence-time distribution, let F(t) be the fraction of eddies with a contact time of less than t. For t ¼ 0, F{t} ¼ 0, and F{t} approaches 1 as t goes to infinity. A plot of F{t} versus t, as shown in Figure 3.19, is a residence-time or age distribution. If F{t} is differentiated with respect to t, fftg ¼ dFftg=dt ð3-195Þ where f{t}dt ¼ the probability that a given surface eddy will have a residence time t. The sum of probabilities is Z 1 0 fftgdt ¼ 1 ð3-196Þ Typical plots of F{t} and f{t} are shown in Figure 3.19, where f{t} is similar to a normal probability curve. For steady-state flow into and out of a well-mixed vessel, Levenspiel shows that Fftg ¼ 1 À eÀt= t ð3-197Þ where  t is the average residence time. This function forms the basis, in reaction engineering, of the ideal model of a contin- uous, stirred-tank reactor (CSTR). Danckwerts selected the same model for his surface-renewal theory, using the corre- sponding f{t} function: fftg ¼ seÀst ð3-198Þ where s ¼ 1= t ð3-199Þ is the fractional rate of surface renewal. As shown in Exam- ple 3.19 below, plots of (3-197) and (3-198) are much differ- ent from those in Figure 3.19. The instantaneous mass-transfer rate for an eddy of age t is given by (3-192) for penetration theory in flux form as NAt ¼ ffiffiffiffiffiffiffiffiffi DAB pt r ðcAi À cAb Þ ð3-200Þ The integrated average rate is ðNA Þ avg ¼ Z 1 0 fftgNAt dt ð3-201Þ §3.6 Models for Mass Transfer in Fluids with a Fluid–Fluid Interface 121

38. Combining (3-198), (3-200), and (3-201) and integrating: ðNA Þ avg

    ¼ ffiffiffiffiffiffiffiffiffiffiffi DAB s p ðcAi À cAb Þ ð3-202Þ Thus, kc ¼ ffiffiffiffiffiffiffiffiffiffiffi DAB s p ð3-203Þ The surface-renewal theory predicts the same dependency of the mass-transfer coefficient on diffusivity as the penetration theory. Unfortunately, s, the fractional rate of surface renewal, is as elusive a parameter as the constant contact time, tc. EXAMPLE 3.19 Application of Surface-Renewal Theory. For the conditions of Example 3.17, estimate the fractional rate of surface renewal, s, for Danckwert’s theory and determine the resi- dence time and probability distributions. Solution From Example 3.17, kc ¼ 6:14 Â 10À3cm/s and DAB ¼ 1:7 Â 10À5cm2/s From (3-203), s ¼ k2 c DAB ¼ ð6:14 Â 10À3Þ2 1:7 Â 10À5 ¼ 2:22 sÀ1 Thus, the average residence time of an eddy at the surface is 1=2.22 ¼ 0.45 s. From (3-198), fftg ¼ 2:22eÀ2:22t ð1Þ From (3-197), the residence-time distribution is FðtÞ ¼ 1 À eÀt=0:45 ð2Þ where t is in seconds. Equations (1) and (2) are shown in Figure 3.20. These curves differ from the curves of Figure 3.19. §3.6.4 Film-Penetration Theory Toor and Marchello [62] combined features of the film, pene- tration, and surface-renewal theories into a film-penetration model, which predicts that the mass-transfer coefficient, kc, varies from ffiffiffiffiffiffiffiffiffi DAB p to DAB , with the resistance to mass transfer residing in a film of fixed thickness d. Eddies move to and from the bulk fluid and this film. Age distributions for time spent in the film are of the Higbie or Danckwerts type. Fick’s second law, (3-68), applies, but the boundary conditions are now cA ¼ cAb at t ¼ 0 for 0 z 1; cA ¼ cAi at z ¼ 0 for t > 0; and cA ¼ cAb at z ¼ d for t > 0 They obtained the following infinite series solutions using La- place transforms. For small values of time, t, NAavg ¼ kc ðcAi À cAb Þ ¼ ðcAi À cAb ÞðsDAB Þ1=2 Â 1 þ 2 X 1 n¼1 exp À2nd ffiffiffiffiffiffiffiffiffi s DAB r   " # ð3-204Þ 1 t 1 e–t/t = 2.22 s–1 {t} F{t} φ (b) t = 0.45 s Area = 1 (a) t = 0.45 s 0 0 0 0 1 t 1 – e–t/t t t Area = t Figure 3.20 Age distribution curves for Example 3.19: (a) F curve; (b) f{t} curve. (a) Total area = 1 Fraction of exit stream older than t1 F{t} {t} φ 1 0 0 t t (b) 0 0 t1 t Figure 3.19 Residence-time distribution plots: (a) typical F curve; (b) typical age distribution. [Adapted from O. Levenspiel, Chemical Reaction Engineering, 2nd ed., John Wiley & Sons, New York (1972).] 122 Chapter 3 Mass Transfer and Diffusion

39. converges rapidly. For large values of t, the following con-

    verges rapidly: NAavg ¼ kc ðcAi À cAb Þ ¼ ðcAi À cAb Þ DAB d   Â 1 þ 2 X 1 n¼0 1 1 þ n2p2 DAB sd2 2 6 4 3 7 5 ð3-205Þ In the limit for a high rate of surface renewal, sd2=DAB , (3-204) reduces to the surface-renewal theory, (3-202). For low rates of renewal, (3-205) reduces to the film theory, (3-188). In between, kc is proportional to Dn AB , where n is 0.5–1.0. Application of the film-penetration theory is difficult because of lack of data for d and s, but the predicted effect of molecular diffusivity brackets experimental data. §3.7 TWO-FILM THEORY AND OVERALL MASS-TRANSFER COEFFICIENTS Gas–liquid and liquid–liquid separation processes involve two fluid phases in contact and require consideration of mass-transfer resistances in both phases. In 1923, Whitman [63] suggested an extension of the film theory to two films in series. Each film presents a resistance to mass transfer, but concentrations in the two fluids at the interface are assumed to be in phase equilibrium. That is, there is no additional interfacial resistance to mass transfer. The assumption of phase equilibrium at the interface, while widely used, may not be valid when gradients of inter- facial tension are established during mass transfer. These gra- dients give rise to interfacial turbulence, resulting, most often, in considerably increased mass-transfer coefficients. This phenomenon, the Marangoni effect, is discussed in detail by Bird, Stewart, and Lightfoot [28], who cite additional references. The effect occurs at vapor–liquid and liquid– liquid interfaces, with the latter having received the most attention. By adding surfactants, which concentrate at the interface, the Marangoni effect is reduced because of inter- face stabilization, even to the extent that an interfacial mass-transfer resistance (which causes the mass-transfer coefficient to be reduced) results. Unless otherwise indicated, the Marangoni effect will be ignored here, and phase equili- brium will always be assumed at the phase interface. §3.7.1 Gas (Vapor)–Liquid Case Consider steady-state mass transfer of A from a gas, across an interface, and into a liquid. It is postulated, as shown in Figure 3.21a, that a thin gas film exists on one side of the interface and a thin liquid film exists on the other side, with diffusion controlling in each film. However, this postulation is not necessary, because instead of writing NA ¼ ðDAB Þ G dG ðcAb À cAi Þ G ¼ ðDAB Þ L dL ðcAi À cAb Þ L ð3-206Þ the rate of mass transfer can be expressed in terms of mass- transfer coefficients determined from any suitable theory, with the concentration gradients visualized more realistically as in Figure 3.21b. Any number of different mass-transfer coefficients and driving forces can be used. For the gas phase, under dilute or equimolar counterdiffusion (EMD) condi- tions, the mass-transfer rate in terms of partial pressures is: NA ¼ kp ðp Ab À p Ai Þ ð3-207Þ where kp is a gas-phase mass-transfer coefficient based on a partial-pressure driving force. For the liquid phase, with molar concentrations: NA ¼ kc ðcAi À cAb Þ ð3-208Þ At the interface, cAi and p Ai are in equilibrium. Applying a version of Henry’s law different from that in Table 2.3,1 cAi ¼ HA p Ai ð3-209Þ Equations (3-207) to (3-209) are commonly used combina- tions for vapor–liquid mass transfer. Computations of mass- transfer rates are made from a knowledge of bulk concentra- tions cAb and p Ab . To obtain an expression for NA in terms of an overall driving force for mass transfer that includes both (a) (b) cAb pAb cAb pAb pAi cAi pAi cAi Liquid film Liquid phase Liquid phase Gas film Gas phase Gas phase Transport Transport Figure 3.21 Concentration gradients for two-resistance theory: (a) film theory; (b) more realistic gradients. 1Different forms of Henry’s law are found in the literature. They include p A ¼ HA xA ; p A ¼ cA HA ; and y A ¼ HA xA When a Henry’s law constant, HA , is given without citing the defining equa- tion, the equation can be determined from the units of the constant. For example, if the constant has the units of atm or atm/mole fraction, Henry’s law is given by pA ¼ HA xA . If the units are mol/L-mmHg, Henry’s law is p A ¼ cA =HA. §3.7 Two-Film Theory and Overall Mass-Transfer Coefficients 123

40. fluid phases, (3-207) to (3-209) are combined to eliminate the

    interfacial concentrations, cAi and p Ai . Solving (3-207) for p Ai : p Ai ¼ p Ab À NA kp ð3-210Þ Solving (3-208) for cAi : cAi ¼ cAb þ NA kc ð3-211Þ Combining (3-211) with (3-209) to eliminate cAi and com- bining the result with (3-210) to eliminate p Ai gives NA ¼ p Ab HA À cAb ðHA =kp Þ þ ð1=kc Þ ð3-212Þ Overall Mass-Transfer Coefficients. It is customary to de- fine: (1) a fictitious liquid-phase concentration cà A ¼ p Ab HA, which is a fictitious liquid concentration of A in equilibrium with the partial pressure of A in the bulk gas; and (2) an overall mass-transfer coefficient, KL . Now (3-212) is NA ¼ KL ðcà A À cAb Þ ¼ ðcà A À cAb Þ ðHA =kp Þ þ ð1=kc Þ ð3-213Þ where KL is the overall mass-transfer coefficient based on the liquid phase and defined by 1 KL ¼ HA kp þ 1 kc ð3-214Þ The corresponding overall driving force for mass transfer is also based on the liquid phase, given by cà A À cAb À Á . The quan- tities HA =kp and 1=kc are measures of gas and liquid mass- transfer resistances. When 1=kc ) HA =kp, the resistance of the gas phase is negligible and the rate of mass transfer is con- trolled by the liquid phase, with (3-213) simplifying to NA ¼ kc ðcà A À cAb Þ ð3-215Þ so that KL % kc. Because resistance in the gas phase is negligi- ble, the gas-phase driving force becomes p Ab À p Ai À Á % 0, so p Ab % p Ai : Alternatively, (3-207) to (3-209) combine to define an overall mass-transfer coefficient, KG, based on the gas phase: NA ¼ p Ab À cAb =HA ð1=kp Þ þ ð1=HA kc Þ ð3-216Þ In this case, it is customary to define: (1) a fictitious gas-phase partial pressure pà A ¼ cAb =HA , which is the partial pressure of A that would be in equilibrium with the con- centration of A in the bulk liquid; and (2) an overall mass-transfer coefficient for the gas phase, KG, based on a partial-pressure driving force. Thus, (3-216) becomes NA ¼ KG ðp Ab À pà A Þ ¼ ðp Ab À pà A Þ ð1=kp Þ þ ð1=HA kc Þ ð3-217Þ where 1 KG ¼ 1 kp þ 1 HA kc ð3-218Þ Now the resistances are 1=kp and 1=HA kc. If 1=kp ) 1=HA kc, NA ¼ kp ðp Ab À pà A Þ ð3-219Þ so KG % kp. Since the resistance in the liquid phase is then negligible, the liquid-phase driving force becomes cAi À cAb ð Þ % 0, so cAi % cAb . The choice between (3-213) or (3-217) is arbitrary, but is usually made on the basis of which phase has the largest mass-transfer resistance; if the liquid, use (3-213); if the gas, use (3-217); if neither is dominant, either equation is suitable. Another common combination for vapor–liquid mass transfer uses mole-fraction driving forces, which define another set of mass-transfer coefficients ky and kx: NA ¼ ky ðy Ab À y Ai Þ ¼ kx ðxAi À xAb Þ ð3-220Þ Now equilibrium at the interface can be expressed in terms of a K-value for vapor–liquid equilibrium, instead of as a Hen- ry’s law constant. Thus, KA ¼ y Ai =xAi ð3-221Þ Combining (3-220) and (3-221) to eliminate y Ai and xAi , NA ¼ y Ab À xAb ð1=KA ky Þ þ ð1=kx Þ ð3-222Þ Alternatively, fictitious concentrations and overall mass- transfer coefficients can be used with mole-fraction driving forces. Thus, xà A ¼ y Ab =KA and yà A ¼ KA xAb . If the two val- ues of KA are equal, NA ¼ Kx ðxà A À xAb Þ ¼ xà A À xAb ð1=KA ky Þ þ ð1=kx Þ ð3-223Þ and NA ¼ Ky ðy Ab À yà A Þ ¼ y Ab À yà A ð1=ky Þ þ ðKA =kx Þ ð3-224Þ where Kx and Ky are overall mass-transfer coefficients based on mole-fraction driving forces with 1 Kx ¼ 1 KA ky þ 1 kx ð3-225Þ and 1 Ky ¼ 1 ky þ KA kx ð3-226Þ When using handbook or literature correlations to estimate mass-transfer coefficients, it is important to determine which coefficient (kp, kc, ky, or kx) is correlated, because often it is not stated. This can be done by checking the units or the form of the Sherwood or Stanton numbers. Coeffi- cients correlated by the Chilton–Colburn analogy are kc for either the liquid or the gas phase. The various coefficients are related by the following expressions, which are summarized in Table 3.16. 124 Chapter 3 Mass Transfer and Diffusion

41. Liquid phase: kx ¼ kc c ¼ kc rL M

      ð3-227Þ Ideal-gas phase: ky ¼ kp P ¼ ðkc Þ g P RT ¼ ðkc Þ g c ¼ ðkc Þ g rG M   ð3-228Þ Typical units are SI AE kc m/s ft/h kp kmol/s-m2-kPa lbmol/h-ft2-atm ky, kx kmol/s-m2 lbmol/h-ft2 When unimolecular diffusion (UMD) occurs under nondi- lute conditions, bulk flow must be included. For binary mix- tures, this is done by defining modified mass-transfer coefficients, designated with a prime as follows: For the liquid phase, using kc or kx, k0 ¼ k ð1 À xA Þ LM ¼ k ðxB Þ LM ð3-229Þ For the gas phase, using kp, ky, or kc, k0 ¼ k ð1 À y A Þ LM ¼ k ðy B Þ LM ð3-230Þ Expressions for k0 are convenient when the mass-transfer rate is controlled mainly by one of the two resistances. Liter- ature mass-transfer coefficient data are generally correlated in terms of k rather than k0. Mass-transfer coefficients estimated from the Chilton–Colburn analogy [e.g. equations (3-166) to (3-171)] are kc, not k0 c. §3.7.2 Liquid–Liquid Case For mass transfer across two liquid phases, equilibrium is again assumed at the interface. Denoting the two phases by L(1) and L(2), (3-223) and (3-224) become NA ¼ Kð2Þ x ðxð2Þà A À xð2Þ Ab Þ ¼ xð2Þà A À xð2Þ Ab ð1=KDA kð1Þ x Þ þ ð1=kð2Þ x Þ ð3-231Þ and NA ¼ Kð1Þ x ðxð1Þ Ab À xð1Þà A Þ ¼ xð1Þ Ab À xð1Þà A ð1=kð1Þ x Þ þ ðKDA =kð2Þ x Þ ð3-232Þ where KDA ¼ xð1Þ Ai xð2Þ Ai ð3-233Þ §3.7.3 Case of Large Driving Forces for Mass Transfer Previously, phase equilibria ratios such as HA , KA , and KDA have been assumed constant across the two phases. When large driving forces exist, however, the ratios may not be con- stant. This commonly occurs when one or both phases are not dilute with respect to the solute, A, in which case, expres- sions for the mass-transfer flux must be revised. For mole- fraction driving forces, from (3-220) and (3-224), NA ¼ ky ðy Ab À y Ai Þ ¼ Ky ðy Ab À yà A Þ ð3-234Þ Thus, 1 Ky ¼ y Ab À yà A ky ðy Ab À y Ai Þ ð3-235Þ or 1 Ky ¼ ðy Ab À y Ai Þ þ ðy Ai À yà A Þ ky ðy Ab À y Ai Þ ¼ 1 ky þ 1 ky y Ai À yà A y Ab À y Ai   ð3-236Þ From (3-220), kx ky ¼ y Ab À y Ai À Á xAi À xAb ð Þ ð3-237Þ Combining (3-234) and (3-237), 1 Ky ¼ 1 ky þ 1 kx y Ai À yà A xAi À xAb   ð3-238Þ Similarly 1 Kx ¼ 1 kx þ 1 ky xà A À xAi y Ab À y Ai   ð3-239Þ Figure 3.22 shows a curved equilibrium line with values of y Ab ; y Ai ; yà A ; xà A ; xAi , and xAb . Because the line is curved, the vapor–liquid equilibrium ratio, KA ¼ yA =xA , is not constant. As shown, the slope of the curve and thus, KA , decrease with Table 3.16 Relationships among Mass-Transfer Coefficients Equimolar Counterdiffusion (EMD): Gases: NA ¼ kyDy A ¼ kcDcA ¼ kpDp A ky ¼ kc P RT ¼ kp P if ideal gas Liquids: NA ¼ kxDxA ¼ kcDcA kx ¼ kc c; where c ¼ total molar concentration ðA þ BÞ Unimolecular Diffusion (UMD) with bulk flow: Gases: Same equations as for EMD with k replaced by k0 ¼ k ðy B Þ LM Liquids: Same equations as for EMD with k replaced by k0 ¼ k ðXB Þ LM When working with concentration units, it is convenient to use: kG ðDcG Þ ¼ kc ðDcÞ for the gas phase kL ðDcL Þ ¼ kc ðDcÞ for the liquid phase §3.7 Two-Film Theory and Overall Mass-Transfer Coefficients 125

42. increasing concentration of A. Denoting two slopes of the equilibrium

    curve by mx ¼ y Ai À yà A xAi À xAb   ð3-240Þ and my ¼ y Ab À y Ai xà A À xAi   ð3-241Þ then substituting (3-240) and (3-241) into (3-238) and (3-239), respectively, 1 Ky ¼ 1 ky þ mx kx ð3-242Þ and 1 Kx ¼ 1 kx þ 1 my ky ð3-243Þ EXAMPLE 3.20 Absorption of SO2 into Water. Sulfur dioxide (A) is absorbed into water in a packed column, where bulk conditions are 50C, 2 atm, y Ab ¼ 0:085, and xAb ¼ 0:001. Equilibrium data for SO2 between air and water at 50C are p SO2 ; atm cSO2 ; lbmol/ft3 0.0382 0.00193 0.0606 0.00290 0.1092 0.00483 0.1700 0.00676 Experimental values of the mass-transfer coefficients are: Liquid phase: kc ¼ 0:18 m/h Gas phase: kp ¼ 0:040 kmol h-m2-kPa For mole-fraction driving forces, compute the mass-transfer flux: (a) assuming an average Henry’s law constant and a negligible bulk- flow effect; (b) utilizing the actual curved equilibrium line and as- suming a negligible bulk-flow effect; (c) utilizing the actual curved equilibrium line and taking into account the bulk-flow effect. In ad- dition, (d) determine the magnitude of the two resistances and the values of the mole fractions at the interface that result from part (c). Solution Equilibrium data are converted to mole fractions by assuming Dal- ton’s law, yA = pA =P, for the gas and xA ¼ cA =c for the liquid. The concentration of liquid is close to that of water, 3.43 lbmol/ft3 or 55.0 kmol/m3. Thus, the mole fractions at equilibrium are: y SO2 xSO2 0.0191 0.000563 0.0303 0.000846 0.0546 0.001408 0.0850 0.001971 These data are fitted with average and maximum absolute deviations of 0.91% and 1.16%, respectively, by the equation y SO2 ¼ 29:74xSO2 þ 6;733x2 SO2 ð1Þ Differentiating, the slope of the equilibrium curve is m ¼ dy dx ¼ 29:74 þ 13;466xSO2 ð2Þ The given mass-transfer coefficients are converted to kx and ky by (3-227) and (3-228): kx ¼ kc c ¼ 0:18ð55:0Þ ¼ 9:9 kmol h-m2 ky ¼ kp P ¼ 0:040ð2Þð101:3Þ ¼ 8:1 kmol h-m2 (a) From (1) for xAb ¼ 0:001; yà A ¼ 29:74ð0:001Þ þ 6;733ð0:001Þ2 ¼ 0:0365. From (1) for y Ab ¼ 0:085, solving the quadratic equation yields xà A ¼ 0:001975. The average slope in this range is m ¼ 0:085 À 0:0365 0:001975 À 0:001 ¼ 49:7 Examination of (3-242) and (3-243) shows that the liquid- phase resistance is controlling because the term in kx is much larger than the term in ky . Therefore, from (3-243), using m ¼ mx, 1 Kx ¼ 1 9:9 þ 1 49:7ð8:1Þ ¼ 0:1010 þ 0:0025 ¼ 0:1035 or Kx ¼ 9:66 kmol h-m2 From (3-223), NA ¼ 9:66ð0:001975 À 0:001Þ ¼ 0:00942 kmol h-m2 (b) From part (a), the gas-phase resistance is almost negligible. Therefore, y Ai % y Ab and xAi % xà A . From (3-241), the slope my is taken at the point y Ab ¼ 0:085 and xà A ¼ 0:001975 on the equilibrium line. By (2), my ¼ 29.74 + 13,466(0.001975) ¼ 56.3. From (3-243), Kx ¼ 1 ð1=9:9Þ þ ½1=ð56:3Þð8:1ފ ¼ 9:69 kmol h-m2 giving NA ¼ 0.00945 kmol/h-m2. This is a small change from part (a). Slope m y xA yA yAi xAi xAb yAb xA * is a fictitious xA in equilibrium with yAb . yA * is a fictitious yA in equilibrium with xAb . Slope m x yA * xA * Figure 3.22 Curved equilibrium line. 126 Chapter 3 Mass Transfer and Diffusion

43. (c) Correcting for bulk flow, from the results of parts

    (a) and (b), y Ab ¼ 0:085; y Ai ¼ 0:085; xAi ¼ 0:1975; xAb ¼ 0:001; ðy B Þ LM ¼ 1:0 À 0:085 ¼ 0:915; and ðxB Þ LM % 0:9986 From (3-229), k0 x ¼ 9:9 0:9986 ¼ 9:9 kmol h-m2 and k0 y ¼ 8:1 0:915 ¼ 8:85 kmol h-m2 From (3-243), Kx ¼ 1 ð1=9:9Þ þ ½1=56:3ð8:85ފ ¼ 9:71 kmol h-m2 From (3-223), NA ¼ 9:7ð0:001975 À 0:001Þ ¼ 0:00947 kmol h-m2 which is only a very slight change from parts (a) and (b), where the bulk-flow effect was ignored. The effect is very small because it is important only in the gas, whereas the liquid resistance is controlling. (d) The relative magnitude of the mass-transfer resistances is 1=my k0 y 1=k0 x ¼ 1=ð56:3Þð8:85Þ 1=9:9 ¼ 0:02 Thus, the gas-phase resistance is only 2% of the liquid-phase resist- ance. The interface vapor mole fraction can be obtained from (3-223), after accounting for the bulk-flow effect: y Ai ¼ y Ab À NA k0 y ¼ 0:085 À 0:00947 8:85 ¼ 0:084 Similarly, xAi ¼ NA k0 x þ xAb ¼ 0:00947 9:9 þ 0:001 ¼ 0:00196 §3.8 MOLECULAR MASS TRANSFER IN TERMS OF OTHER DRIVING FORCES Thus far in this chapter, only a concentration driving force (in terms of concentrations, mole fractions, or partial pressures) has been considered, and only one or two species were trans- ferred. Molecular mass transfer of a species such as a charged biological component may be driven by other forces besides its concentration gradient. These include gradients in temper- ature, which induces thermal diffusion via the Soret effect; pressure, which drives ultracentrifugation; electrical poten- tial, which governs electrokinetic phenomena (dielectro- phoresis and magnetophoresis) in ionic systems like permselective membranes; and concentration gradients of other species in systems containing three or more compo- nents. Three postulates of nonequilibrium thermodynamics may be used to relate such driving forces to frictional motion of a species in the Maxwell–Stefan equations [28, 75, 76]. Maxwell, and later Stefan, used kinetic theory in the mid- to late-19th century to determine diffusion rates based on momentum transfer between molecules. At the same time, Graham and Fick described ordinary diffusion based on bi- nary mixture experiments. These three postulates and applications to bioseparations are presented in this section. Application of the Maxwell–Stefan equations to rate-based models for multicomponent absorption, stripping, and distil- lation is developed in Chapter 12. §3.8.1 The Three Postulates of Nonequilibrium Thermodynamics This brief introduction summarizes a more detailed synopsis found in [28]. First postulate The first (quasi-equilibrium) postulate states that equilibrium thermodynamic relations apply to systems not in equilibrium, provided departures from local equilibrium (gradients) are sufficiently small. This postulate and the second law of ther- modynamics allow the diffusional driving force per unit vol- ume of solution, represented by cRTdi and which moves species i relative to a solution containing n components, to be written as cRTdi  ci rT;Pmi þ ci Vi À vi À Á rP À ri gi À X n k¼1 vkgk ! ð3-244Þ X n i¼1 di ¼ 0 ð3-245Þ where di are driving forces for molecular mass transport, ci is molar concentration, mi is chemical potential, vi is mass frac- tion, gi are total body forces (e.g., gravitational or electrical potential) per unit mass, Vi is partial molar volume, and ri is mass concentration, all of which are specific to species i. Each driving force is given by a negative spatial gradient in potential, which is the work required to move species i rela- tive to the solution volume. In order from left to right, the three collections of terms on the RHS of (3-244) represent driving forces for concentration diffusion, pressure diffusion, and forced diffusion. The term ci Vi in (3-244) corresponds to the volume fraction of species i, fi. Second postulate The second (linearity) postulate allows forces on species in (3-244) to be related to a vector mass flux, ji. It states that all fluxes in the system may be written as linear relations involv- ing all the forces. For mass flux, the thermal-diffusion driving force, Àbi0 r ln T, is added to the previous three forces to give ji ¼ Àbi0 r ln T À ri X n j¼1 bij ri rj cRTdj ð3-246Þ bij þ X n k¼1 k6¼j bik ¼ 0 ð3-247Þ where bi0 and bij are phenomenological coefficients (i.e., transport properties). The vector mass flux, ji ¼ ri(vi À v), is the arithmetic average of velocities of all molecules of §3.8 Molecular Mass Transfer in Terms of Other Driving Forces 127

44. species i in a tiny volume element (vi) relative to

    a mass- averaged value of the velocities of all such components in the mixture, v ¼ P vi vi. It is related to molar flux, Ji, in (3-251). Third postulate According to the third postulate, Onsager’s reciprocal rela- tions—developed using statistical mechanics and supported by data—the matrix of the bij coefficients in the flux-force relation (3-246) are symmetric (bij ¼ bji) in the absence of magnetic fields. These coefficients may be rewritten as multi- component mass diffusivities D0 ij D0 ij ¼ xi xj bij cRT ¼ D0 ji À Á ð3-248Þ which exhibit less composition dependency than the trans- port properties, bij, and reduce to the more familiar binary diffusivity of Fick’s Law, DAB , for ideal binary solutions, as shown in Figure 3.23, and illustrated in Example 3.21. §3.8.2 Maxwell–Stefan Equations To show the effects of forces on molecular motion of species i, (3-248) is substituted into (3-246), which is solved for the driving forces, di, and set equal to (3-244). Using ji ¼ ri(vi À v), discussed above, a set of n À 1 independent rate expres- sions, called the Maxwell–Stefan equations, is obtained: X n j¼1 xi xj D0 ij vi À vj À Á ¼ 1 cRT " ci rT;Pmi þ fi À vi ð ÞrP À ri gi À X n k¼1 vkgk !# À X n j¼1 xi xj D0 ij bi0 ri À bj0 rj ! r lnT ð3-249Þ The set of rate expressions given by (3-249) shows molec- ular mass transport of species i driven by gradients in pressure, temperature, and concentration of species i for j 6¼ i in systems containing three or more components, as well as driven by body forces that induce gradients in potential. The total driving force for species i due to potential gradients col- lected on the LHS of (3-249) is equal to the sum on the RHS of the cumulative friction force exerted on species i—zi,j xj (xi À xj)—by every species j in a mixture, where frictional coefficient zij is given by xi =D0 ij in (3-249). The friction exerted by j on i is proportional to the mole fraction of j in the mixture and to the difference in average molecular veloc- ity between species j and i. Body forces in (3-249) may arise from gravitational accel- eration, g; electrostatic potential gradients, rw, or mechani- cally restraining matrices (e.g., permselective membranes and friction between species i and its surroundings), denoted by dim. These can be written as gi ¼ g À zi = Mi   rw þ dim 1 rm rP ð3-250Þ where zi is elementary charge and Faraday’s constant, =, ¼ 96,490 absolute coulombs per gram-equivalent. Chemical versus physical potentials Potential can be defined as the reversible work required to move an entity relative to other elements in its surroundings. The change in potential per unit distance provides the force that drives local velocity of a species relative to its environ- ment in (3-249). For molecules, potential due to gravity in (3-250)—an external force that affects the whole system—is insignificant relative to chemical potential in (3-249), an in- ternal force that results in motion within the system but not in the system as whole. Gravity produces a driving force downward at height z, resulting from a potential difference due to the work performed to attain the height, ÀmgDz, divided by the height, Dz, which reduces to mg. For gold (a dense molecule), this driving force ¼ ð0:197 kg/molÞ ð10 m/s2Þ ffi 2 N/mol. Gravitational potential of gold across the distance of a centimeter is therefore 2 Â 10À2 N/mol. Chemical potential can be defined as the reversible work needed to separate one mole of species i from a large amount of a mixture. Its magnitude increases logarithmically with the species activity, or Dm ¼ ÀRTD ln(gi xi). Gold, in an ideal solution (gi ¼ 1) and for ambient conditions at xi ¼ 1/e ¼ 0.368, experiences a driving force times distance due to a chemical potential of À(8.314 J/mol–K)(298 K) Â ln (0.37) ¼ 2,460 J/mol. The predominance of chemical poten- tial leads to an approximate linear simplification of (3-249)— which neglects potentials due to pressure, temperature, and external body forces—that is applicable in many practical sit- uations, as illustrated later in Example 3.25. Situations in which the other potentials are significant are also considered. For instance, Example 3.21 below shows that ultra- centrifugation provides a large centripetal (‘‘center-seek- ing’’) force to induce molecular momentum, rP, sufficient to move species i in the positive direction, if its mass fraction is greater than its volume fraction (i.e., if component i is denser than its surroundings). 2.0 Mole fraction ether Activity 1.0 0 1.0 2.5 D’AB DAB Figure 3.23 Effect of activity on the product of viscosity and diffusivity for liquid mixtures of chloroform and diethyl ether [R.E. Powell, W.E. Roseveare, and H. Eyring, Ind. Eng. Chem., 33, 430– 435 (1941)]. 128 Chapter 3 Mass Transfer and Diffusion

45. Driving forces for species velocities Effects of driving forces on

    species velocity are illustrated in the following seven examples reduced from [28], [75], [76], and [77]. These examples show how to apply (3-249) and (3-250), together with species equations of continuity, the equation of motion, and accompanying auxiliary (bootstrap) relations such as (3-245) and (3-248). The auxiliary expres- sions are needed to provide the molecular velocity of the se- lected reference frame because the velocities in (3-249) are relative values. The first example considers concentration- driving forces in binary systems. Measured data for D0 ij, which requires simultaneous measurement of gi as a function of xi, are rare. Instead, the multicomponent diffusivity values may be estimated from phenomenological Fick’s law diffusivities. EXAMPLE 3.21 Maxwell–Stefan Equations Related to Fick’s Law. Consider a binary system containing species A and B that is iso- tropic in all but concentration [75]. Show the correspondence between DAB and D0 AB by relating (3-249) to the diffusive molar flux of species A relative to the molar-average velocity of a mixture, JA , which may be written in terms of the mass-average velocity, jA : JA ¼ ÀcDAB rxA ¼ cA vA À vM ð Þ ¼ jA cxA xB rvA vB ð3-251Þ where vM ¼ xA vA þ xB vB is the molar-average velocity of a mixture. Solution In a binary system, xB ¼ 1 À xA , and the LHS of (3-249) may be written as xA xB D0 AB vB À vA ð Þ ¼ xA D0 AB xB vB þ xA vA À vA ð Þ ¼ À xA D0 AB JA cA ð3-252Þ which relates the friction force to the molar flux. Substituting rmi ¼ RTrln(ai) into the RHS of (3-249), setting it equal to (3-252), and rearranging, gives JA ¼ ÀcD0 AB xA r ln aA þ 1 cRT fA À vA ð ÞrP ½ & ÀrvA vB gA À gB ð ފ þ kT r ln Tg ð3-253Þ kT ¼ bA0 rD0 AB xA xB vA vB ¼ aT xA xB ¼ sT xA xB T ð3-254Þ Equation (3-253) describes binary diffusion in gases or liquids. It is a specialized form of the generalized Fick equations. Equation (3- 254) relates the thermal diffusion ratio, kT, to the thermal diffusion factor, aT, and the Soret coefficient, sT. For liquids, sT is preferred. For gases, aT is nearly independent of composition. Table 3.17 shows concentration- and temperature-dependent kT values for several binary gas and liquid pairs. Species A moves to the colder region when the value of kT is positive. This usually cor- responds to species A having a larger molecular weight (MA ) or diameter. The sign of kT may change with temperature. In this example, the effects of pressure, thermal diffusion, and body force terms in (3-253) may be neglected. Then from the properties of logarithms, xA r ln aA ¼ rxA þ xA r ln gA ¼ rxA 1 þ q ln gA q ln xA   ð3-255Þ By substituting (3-255) into (3-253) and comparing with (3-251), it is found that DAB ¼ 1 þ q ln gA q ln xA   D0 AB ð3-256Þ The activity-based diffusion coefficient D0 AB is less concentration- dependent than DAB but requires accurate activity data, so it is used less widely. Multicomponent mixtures of low-density gases have gi ¼ 1 and di ¼ rxi for concentration diffusion and DAB ¼ D0 AB from kinetic theory. EXAMPLE 3.22 Diffusion via a Thermal Gradient (thermal diffusion). Consider two bulbs connected by a narrow, insulated tube that are filled with a binary mixture of ideal gases [28]. (Examples of binary mixtures are given in Table 3.17.) Maintaining the two bulbs at con- stant temperatures T2 and T1 , respectively, typically enriches the larger species at the cold end for a positive value of kT. Derive an expression for (xA2 À xA1 ), the mole-fraction difference between the two bulbs, as a function of kT, T2 , and T1 at steady state, neglec- ting convection currents in the connecting tube. Solution There is no net motion of either component at steady state, so JA ¼ 0. Use (3-253) for the ideal gases (gA ¼ 1), setting the connecting tube on the z-axis, neglecting pressure and body forces, and apply- ing the properties of logarithms to obtain dxA dz ¼ À kT T dT dz ð3-257Þ Table 3.17 Experimental Thermal Diffusion Ratios for Low-Density Gas and Liquid Mixtures Species A-B T(K) xA kT {xA ,T} Gas Ne-He 330 0.80 0.0531 0.40 0.1004 N2 -H2 264 0.706 0.0548 0.225 0.0663 D2 -H2 327 0.90 0.1045 0.50 0.0432 0.10 0.0166 Liquid C2 H2 Cl4 -n-C6 H14 298 0.5 1.08 C2 H4 Br2 -C2 H4 Cl2 298 0.5 0.225 C2 H2 Cl4 -CCl4 298 0.5 0.060 CBr4 -CCl4 298 0.09 0.129 CCl4 -CH3 OH 313 0.5 1.23 CH3 OH-H2 O 313 0.5 À0.137 Cyclo-C6 H12 -C6 H6 313 0.5 0.100 Data from Bird et al. [28]. §3.8 Molecular Mass Transfer in Terms of Other Driving Forces 129

46. The integral of (3-257) may be evaluated by neglecting composition

    effects on kT for small differences in mole fraction and using a value of kT at a mean temperature, Tm, to yield xA2 À xA1 ¼ ÀkT Tm f gln T2 T1 ð3-258Þ where the mean temperature at which to evaluate kT is Tm ¼ T1 T2 T2 À T1 ln T2 T1 ð3-259Þ Substituting values of kT from Table 3.17 into (3-258) suggests that a very large temperature gradient is required to obtain more than a small composition difference. During World War II, uranium iso- topes were separated in cascades of Clausius–Dickel columns based on thermal diffusion between sets of vertical heated and cooled walls. The separation supplemented thermal diffusion with free con- vection to allow species A, enriched at the cooled wall, to descend and species B, enriched at the heated wall, to ascend. Energy expen- ditures were enormous. EXAMPLE 3.23 Diffusion via a Pressure Gradient (pressure diffusion). Components A and B in a small cylindrical tube of length L, held at radial position Ro ) L inside an ultracentrifuge, are rotated at con- stant angular velocity V [28]. The species experience a change in molecular momentum, rp, due to centripetal (‘‘center-seeking’’) acceleration gV ¼ V2r given by the equation of motion, dp dr ¼ rgV ¼ rV2r ¼ r v2 u r ð3-260Þ where vu ¼ du Vr is the linear velocity. Derive expressions for (1) the migration velocity, vmigr , of dilute A in B (e.g., protein in H2 O) in terms of relative molecular weight, and for (2) the distribution of the two components at steady state in terms of their partial molar volumes,  Vi , i ¼ A, B, and the pressure gradient, neglecting changes in  Vi and gi over the range of conditions in the centrifuge tube. Solution The radial motion of species A is obtained by substituting (3-255) into the radial component of the binary Maxwell–Stefan equation in (3-253) for an isothermal tube free of external body forces to give JA ¼ ÀcD0 AB 1 þ qlngA qlnxA   dxA dr þ 1 cRT fA À vA ð Þ dP dr ! ð3-261Þ where the pressure gradient of the migration term in (3-261) remains relatively constant in the tube since L ( Ro . Molecular-weight de- pendence in this term in the limit of a dilute solution of protein (A) in H2 O (B) arises in the volume and mass fractions, respectively, wA ¼ cA VA ¼ xA cVA % xA VA VB ¼ xA MA MB ^ VA ^ VB ð3-262Þ vA ¼ rA r ¼ cA MA cM ¼ xA MA xA MA þ xB MB % xA MA MB ð3-263Þ where ^ Vi ¼  Vi =Mi is the partial specific volume of species i, which is 1 mL/g for H2 O and $0.75 mL/g for a globular protein (see Table 3.18). A pseudo-binary Fickian diffusivity given by (3-256) to be substituted into (3-261) may be estimated using Stokes law: DAB ¼ kT 6pmB RA f A ð3-264Þ where RA is the radius of a sphere whose volume equals that of the protein, and protein nonsphericity is accounted for by a hydro- dynamic shape factor, fA . Substituting (3-256), (3-260), (3-262), and (3-263) into (3-261) gives JA ¼ ÀcDAB dxA dr þ cA À D0 AB cRT MA MB ^ VA ^ VB À 1   ! rV2r & ' ð3-265Þ where the term inside the curly brackets on the RHS of (3-265) cor- responds to the migration velocity, vmigr , in the +r direction driven by centripetal force in proportion to the relative molecular weight, MA =MB . The ratio of vmigr to centripetal force in (3-265) is the sedi- mentation coefficient, s, which is typically expressed in Svedberg (S) units (1 S ¼ 10À13 sec), named after the inventor of the ultra- centrifuge. Protein molecular-weight values obtained by photo- electric scanning detection of vmigr to determine s in pure water (w) at 20 (i.e., s20,w) are summarized in Table 3.18. Equation (3-265) is the basis for analyzing transient behavior, steady polarization, and preparative application of ultracentrifugation. Concentration and pressure gradients balance at steady state (JA ¼ 0), and with constant  Vi and gi in the tube and xA $ xB lo- cally, writing (3-253) for species A gives 0 ¼ dxA dr þ MA xA RT VA MA À 1 r   dp dr ð3-266Þ Multiplying (3-266) by ð VB =xA Þdr, and substituting a constant cen- tripetal force (r % Ro ) from (3-260), gives VB dxA xA ¼ VB gV RT rVA À MA À Á dr ð3-267Þ Writing an equation analogous to (3-267) for species B, and sub- tracting it from (3-267), gives VB dxA xA À VA dxB xB ¼ gV RT MA VB À MB VA À Á dr ð3-268Þ Integrating (3-268) from xi{r ¼ 0} ¼ xi0 to xi{r} for i ¼ A,B, using r ¼ 0 at the distal tube end, gives VB ln xA xA0 À VA ln xB xB0 ¼ gV RT MB VA À MA VB À Á r ð3-269Þ Table 3.18 Protein Molecular Weights Determined by Ultracentrifugation Protein M s20,w (S) V2 (cm3gÀ1) Ribonuclease (bovine) 12,400 1.85 0.728 Lysozyme (chicken) 14,100 1.91 0.688 Serum albumin (bovine) 66,500 4.31 0.734 Hemoglobin 68,000 4.31 0.749 Tropomysin 93,000 2.6 0.71 Fibrinogen (human) 330,000 7.6 0.706 Myosin (rod) 570,000 6.43 0.728 Bushy stunt virus 10,700,000 132 0.74 Tobacco mosaic virus 40,000,000 192 0.73 Data from Cantor and Schimmel [78]. 130 Chapter 3 Mass Transfer and Diffusion

47. Using the properties of logarithms and taking the exponential of

    both sides of (3-269) yields the steady-state species distribution in terms of the partial molar volumes: xA xA0  VB xB0 xB  VA ¼ exp gV r RT MB VA À MA VB À Á h i ð3-270Þ The result in (3-269) is independent of transport coefficients and may thus be obtained in an alternative approach using equilibrium thermodynamics. EXAMPLE 3.24 Diffusion in a Ternary System via Gradients in Concentration and Electrostatic Potential. A 1-1 electrolyte M+XÀ (e.g., NaCl) diffuses in a constriction bet- ween two well-mixed reservoirs at different concentrations contain- ing electrodes that exhibit a potential difference, Dw, measured by a potentiometer under current-free conditions [75]. Derive an expres- sion for salt flux in the system. Solution Any pressure difference between the two reservoirs is negligible rel- ative to the reference pressure, cRT $ 1,350 atm, at ambient condi- tions. Electroneutrality, in the absence of current flow through the potentiometer, requires that xMþ ¼ xXÀ ¼ xS ¼ 1 À xW ð3-271Þ NMþ ¼ NXÀ ¼ NS ð3-272Þ Substituting (3-271) into (3-249) and rearranging yields the n À 1 Maxwell–Stefan relations: 1 cD0 MþW xW NMþ À xMþ NW ð Þ ¼ ÀxMþ rT;P aMþ þ rMþ cRT gMþ À X n k¼1 vkgk ! ð3-273Þ 1 cD0 XÀW xW NXÀ À xXÀ NW ð Þ ¼ ÀxXÀ rT;P aXÀ þ rXÀ cRT gXÀ À X n k¼1 vkgk ! ð3-274Þ No ion-ion diffusivity appears because vMþ À vXÀ ¼ 0 in the absence of current. Substituting (3-250), (3-271), and (3-272) into (3-273) and (3-274) and rearranging yields 1 cD0 MþW xW NS À xS NW ð Þ ¼ À q ln aMþ q ln xS rxS À xS RT =rw ð3-275Þ 1 cD0 XÀW xW NS À xS NW ð Þ ¼ À q ln aXÀ q ln xS rxS þ xS RT =rw ð3-276Þ Adding (3-275) and (3-276) eliminates the electrostatic potential, to give NS ¼ À 1 cD0 MþW þ 1 cD0 XÀW   À1 q ln aMþ aXÀ ð Þ q ln xS rxS þ xS NS þ NW ð Þ ð3-277Þ which has the form of Fick’s law after a concentration-based diffusiv- ity is defined: DSW ¼ 2 D0 MþW D0 XÀW D0 MþW þ D0 XÀW   1 þ q ln gS q ln xS   ð3-278Þ gS ¼ gMþ gXÀ ð3-279Þ where gS is the mean activity coefficient given by aS ¼ aM þ aXÀ ¼ x2 s ½ðgM þ g XÀ Þ1=2Š2 ¼ x2 s ½ðgS Þ1=2Š2. Equation (3-278) shows that while fast diffusion of small counterions creates a potential gradient that speeds large ions, the overall diffusivity of the salt pair is domi- nated by the slower ions (e.g., proteins). EXAMPLE 3.25 Film Mass Transfer. Species velocity in (3-249) is due to (1) bulk motion; (2) gradient of a potential Dci ¼ cid À cio of species i across distance d (which moves species i relative to the mixture); and (3) friction between species and surroundings [77]. Develop an approximate expression for film mass transfer using linearized potential gradients. Solution The driving force that results from the potential gradient, Àdci =dz, is approximated by the difference in potential across a film of thick- ness d, ÀDci =d. Linearizing the chemical potential difference by Dmi ¼ RTDln gi xi ð Þ % RT xid À xio xid þ xio ð Þ=2 ¼ RT Dxi  xi ð3-280Þ provides a tractable approximation that has reasonable accuracy over a wide range of compositions [77]. Friction from hydrodynamic drag of fluid (1) of viscosity m1 on a spherical particle (2) of diameter d2 is proportional to their relative difference in velocity, v, viz., À dm2 dz ¼ 3NA pm1 v2 À v1 ð Þd2 ð3-281Þ where NA (Avogadro’s number) represents particles per mole. A large force is produced when the drag is summed over a mole of particles. Rearranging (3-281) yields an expression for the Maxwell– Stefan diffusivity in terms of hydrodynamic drag: À d dz m2 RT   ¼ v2 À v1 D0 12 ð3-282Þ D0 12 ¼ RT NA3ph1 d2 ð3-283Þ Substituting (3-280) into (3-282) and rearranging, after linearizing the derivative across a film of thickness d, yields the mass transport coefficient, k12 , Dx2  x2 ¼  v1 À  v2 k12 ð3-284Þ k12 ¼ D0 12 d ð3-285Þ where kij is $10À1 m/s for gases and 10À4 m/s for liquids. These values decrease by approximately a factor of 10 for gases and liquids in porous media. In a general case that includes any number of components, fric- tion between components j and i per mole of i is proportional to the difference between the mean velocities of j and i, respectively. §3.8 Molecular Mass Transfer in Terms of Other Driving Forces 131

48. Taking friction proportional to the local concentration of j decreases

    the composition dependence of kij, viz.,  xj  vj À  vi kij ð3-286Þ Because assigning a local concentration to a component like a solid membrane component, m, is difficult, a membrane coefficient, ki, may be introduced instead:  xm kim ¼ 1 ki ð3-287Þ §3.8.3 Maxwell–Stefan Difference Equation Linearization allows application of a difference form of the Maxwell–Stefan equation, which is obtained by setting the negative driving force on species i equal to the friction on species i, viz. [77]: Dxi  xi þ ::: ¼ X j  xj  vj À  vi kij ð3-288Þ where the ellipsis . . . allows addition of relevant linearized potentials in addition to the chemical potential. The accuracy of (3-288) is adequate for many engineering calculations. This is illustrated by determining molar solute flux of dilute and nondilute solute during binary stripping, and by estimat- ing concentration polarization and permeate flux in tangen- tial-flow filtration. Dilute stripping Consider stripping a trace gas (1) ð x2 % 1Þ from a liquid through a gas film into an ambient atmosphere. The atmosphere is taken at a reference velocity (v2 ¼ 0). Application of (3-288) yields k12 Dx1  x1 ¼ À v1 ð3-289Þ or N1 ¼ c v1  x1 ¼ Àck12 Dx1 ð3-290Þ The result in (3-290), obtained from the Maxwell–Stefan dif- ference equation, is consistent with (3-35) for dilute (x2 $1) solutions, which was obtained from Fick’s law. Nondilute stripping For this situation,  x1 ¼ 0:5 ¼  x2, and drift occurs in the gas film. From (3-288), k12 Dx1  x1 ¼ À0:5 Á  v1 ð3-291Þ for which N1 ¼ c v1  x1 ¼ À2ck12 Dx1 ð3-292Þ The latter result is easily obtained using (3-288) without requiring a drift-correction, as Fick’s law would have. Concentration polarization in tangential flow filtration Now consider the flux of water (2) through a semipermeable membrane that completely retains a dissolved salt (1) at dilute concentration (x2 % 1), as discussed in [77]. Set the velocity of the salt equal to a stationary value in the frame of reference (v1 ¼ 0). The average salt concentration in a film of thickness d adjacent to the membrane is  x1 ¼ x1o þ x1d À x1o 2 ¼ x1o þ Dx1 2 ð3-293Þ Using (3-288) gives k12 Dx1  x1 ¼  v2 ð3-294Þ Combining (3-293) and (3-294) gives the increase in salt con- centration in the film relative to its value in the bulk: Dx1 x1o ¼ 2  v2 k12 2 À  v2 k12 ð3-295Þ EXAMPLE 3.26 Flux in Tangential-Flow Filtration. Relate flux of permeate, j, in tangential-flow filtration to local wall concentration of a completely retained solute, i, using the Maxwell– Stefan difference equation. Solution Local permeate flux is given by Nj ¼  cj  vj. An expression for local water velocity is obtained by solving (3-295) for  vj:  vj ¼ kij Dxi Dxi =2 þ xi;b % kijln xi;w xi;b ð3-296Þ where subscripts b and w represent bulk feed and wall, respectively. In a film, kij ¼ Dij =d. Local permeate flux is then Nj ¼ cj Dij d ln xi;w xi;b ð3-297Þ The result is consistent with the classical stagnant-film model in (14-108), which was obtained using Fick’s law. EXAMPLE 3.27 Maxwell–Stefan Difference Equations Related to Fick’s Law. For a binary system containing species A and B, show how DAB re- lates to D0 AB in the Maxwell–Stefan difference equation by relating (3-288) with the diffusive flux of species A relative to the molar-av- erage velocity of a mixture in (3-3a), JAz ¼ ÀDAB dcA dz ¼ cA vA À vM ð Þ ð3-298Þ where vM ¼ xA vA þ xB vB is the molar-average velocity of a mixture. Solution For a binary system, (3-288) becomes 1 xA dxA dz ¼  xB  vB À  vA D0 AB ¼  xB  vB þ  xA  vA À  vA D0 AB ¼ À  vA À vM D0 AB ð3-299Þ 132 Chapter 3 Mass Transfer and Diffusion

49. Comparing (3-298) and (3-299) shows that for the Maxwell– Stefan

    difference equation D0 AB ¼ DAB ð3-300Þ The result in (3-300) is consistent with kinetic theory for multi- component mixtures of low-density gases, for which gi ¼ 1 and di ¼ rxi for concentration diffusion. This abbreviated introduction to the Maxwell–Stefan rela- tions has shown how this kinetic formulation yields diffusive flux of species proportional to its concentration gradient like Fick’s law for binary mixtures, and provides a basis for exam- ining molecular motion in separations based on additional driving forces such as temperature, pressure, and body forces. For multicomponent mixtures that are typical of biosepara- tions, the relations also quantitatively identify how the flux of each species affects the transport of any one species. This ap- proach yields concentration gradients of each species in terms of the fluxes of the other species, which often requires expen- sive computational inversion. Fick’s law may be generalized to obtain single-species flux in terms of concentration gradi- ents for all species, but the resulting Fickian multicomponent diffusion coefficients are conjugates of the binary diffusion coefficients. The linearized Maxwell–Stefan difference equa- tion allows straightforward analysis of driving forces due to concentration-, pressure-, body force-, and temperature- driving forces in complex separations like bioproduct purifica- tion, with accuracy adequate for many applications. SUMMARY 1. Mass transfer is the net movement of a species in a mix- ture from one region to a region of different concentra- tion, often between two phases across an interface. Mass transfer occurs by molecular diffusion, eddy diffusion, and bulk flow. Molecular diffusion occurs by a number of different driving forces, including concentration (ordi- nary), pressure, temperature, and external force fields. 2. Fick’s first law for steady-state diffusion states that the mass-transfer flux by ordinary molecular diffusion is equal to the product of the diffusion coefficient (diffusiv- ity) and the concentration gradient. 3. Two limiting cases of mass transfer in a binary mixture are equimolar counterdiffusion (EMD) and unimolecular dif- fusion (UMD). The former is also a good approximation for distillation. The latter includes bulk-flow effects. 4. When data are unavailable, diffusivities (diffusion coef- ficients) in gases and liquids can be estimated. Diffusivi- ties in solids, including porous solids, crystalline solids, metals, glass, ceramics, polymers, and cellular solids, are best measured. For some solids, e.g., wood, diffusiv- ity is anisotropic. 5. Diffusivities vary by orders of magnitude. Typical values are 0.10, 1 Â 10À5, and 1 Â 10À9 cm2/s for ordinary molecular diffusion of solutes in a gas, liquid, and solid, respectively. 6. Fick’s second law for unsteady-state diffusion is readily applied to semi-infinite and finite stagnant media, including anisotropic materials. 7. Molecular diffusion under laminar-flow conditions is de- termined from Fick’s first and second laws, provided velocity profiles are available. Common cases include falling liquid-film flow, boundary-layer flow on a flat plate, and fully developed flow in a straight, circular tube. Results are often expressed in terms of a mass- transfer coefficient embedded in a dimensionless group called the Sherwood number. The mass-transfer flux is given by the product of the mass-transfer coefficient and a concentration-driving force. 8. Mass transfer in turbulent flow can be predicted by anal- ogy to heat transfer. The Chilton–Colburn analogy uti- lizes empirical j-factor correlations with a Stanton number for mass transfer. A more accurate equation by Churchill and Zajic should be used for flow in tubes, par- ticularly at high Reynolds numbers. 9. Models are available for mass transfer near a two-fluid interface. These include film theory, penetration theory, surface-renewal theory, and the film-penetration theory. These predict mass-transfer coefficients proportional to the diffusivity raised to an exponent that varies from 0.5 to 1.0. Most experimental data provide exponents rang- ing from 0.5 to 0.75. 10. Whitman’s two-film theory is widely used to predict the mass-transfer flux from one fluid, across an interface, and into another fluid, assuming equilibrium at the inter- face. One resistance is often controlling. The theory defines an overall mass-transfer coefficient determined from the separate coefficients for each of the phases and the equilibrium relationship at the interface. 11. The Maxwell–Stefan relations express molecular motion of species in multicomponent mixtures in terms of potential gradients due to composition, pressure, temper- ature, and body forces such as gravitational, centripetal, and electrostatic forces. This formulation is useful to characterize driving forces in addition to chemical potential, that act on charged biomolecules in typical bioseparations. REFERENCES 1. Taylor, R., and R. Krishna, Multicomponent Mass Transfer, John Wiley & Sons, New York (1993). 2. Poling, B.E., J.M. Prausnitz, and J.P. O’Connell, The Properties of Liquids and Gases, 5th ed., McGraw-Hill, New York (2001). References 133

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