Energy Levels and Spectrum of Hydrogenic Atoms

Transcript

1. Energy Levels and Spectrum of Hydrogenic Atoms Michael Papasimeon April

   16, 1998 Michael Papasimeon Hydrogenic Atoms April 16, 1998 1 / 33

2. Hamiltonian for Electron in Coulomb Potential A hydrogenic atom can

   be thought of as an electron with charge (−e) moving around the spherically symmetric Coulomb potential of the nucleus which has charge Z. H = p2 2µ − Ze2 4π 0r . (1) where µ is the reduced mass... µ = Mm M + m (2) Michael Papasimeon Hydrogenic Atoms April 16, 1998 2 / 33

3. Time Independent Schr¨ odinger Equation The problem reduces to solving

   the time independent Schr¨ odinger equation for the above Hamiltonian. p2 2µ − Ze2 4πr ψnlm = Enψnlm (3) Solving for this equation gives the energy levels of hydrogenic atoms En, and and corresponding wavefunctions ψnlm . The energy levels only depend on the principle quantum number n, whereas the wavefunctions also depend on the orbital angular momentum quantum number l (l = 0, 1, ...n − 1) and magnetic quantum number m (m = −l, −l + 1, ..., +l − 1, +l). Michael Papasimeon Hydrogenic Atoms April 16, 1998 3 / 33

4. Wave Functions for Hydrogenic Atoms The wavefunctions of hydrogenic atoms

   are given by ψnlm(r) = ψnlm(r, θ, φ) = Rnl(r)Ylm(θ, φ) (4) where Rnl(r) are the radial wavefunctions and Ylm(θ, φ) are spherical harmonics. The corresponding energy levels of hydrogenic atoms are given by En = − 1 2 µc2 Z2α2 n2 (5) where α is the fine structure constant: α = e2 4π 0 c Michael Papasimeon Hydrogenic Atoms April 16, 1998 4 / 33

5. Energy Levels of Hydrogen Z = 1 00000000000000000000000000000 00000000000000000000000000000 00000000000000000000000000000

   00000000000000000000000000000 00000000000000000000000000000 00000000000000000000000000000 00000000000000000000000000000 11111111111111111111111111111 11111111111111111111111111111 11111111111111111111111111111 11111111111111111111111111111 11111111111111111111111111111 11111111111111111111111111111 11111111111111111111111111111 -14 -13 -12 -11 -10 -9 -8 -7 -6 -5 -4 -3 -2 -1 0 l = 0 l = 1 l = 2 l = 3 l = 4 l = 5 s p d f g h n = 1 n = 2 n = 3 n = 4 n = Inf Energy (eV) E = -13.6 eV E = -3.4 eV E = -1.51 eV E = -0.85 eV Michael Papasimeon Hydrogenic Atoms April 16, 1998 5 / 33

6. Rydberg States A highly excited hydrogenic atom, that is one

   with a large principal quantum number n is said to be known as a Rydberg Atom, or to be in a Rydberg State. The Rydberg Atom with n = 100, is of an extremely large size – approximately the size of a simple bacteria. However, such an atom has a very small ionisation energy and hence the electron is very weakly bound. Table: Bohr orbit radius and binding energy for Hydrogen atoms in the ground state n = 1 and Rydberg state n = 100 Quantity n = 1 n = 100 Bohr Orbit Radius [m] 5.3 × 10−11 5.3 × 10−7 Binding Energy |En| [eV] −13.6 × 100 1.36 × 10−3 Michael Papasimeon Hydrogenic Atoms April 16, 1998 6 / 33

7. Hydrogenic Spectrum 0 20 40 60 80 100 1 2

   3 4 5 Frequency Lyman Series Balmer Series Paschen Series Brackett Series -0.85 -1.51 -3.4 -13.6 E (eV) Michael Papasimeon Hydrogenic Atoms April 16, 1998 7 / 33

8. Lyman, Balmer and Paschen Spectral Lines Lyman Series (Ultra Violet

   Region) Spectral Line Wavelength ( ˚ A) Lyα 1216 Lyβ 1026 Lyγ 972.5 Lyδ 949.7 Balmer Series (Visible–Ultra Violet Region) Spectral Line Wavelength ( ˚ A) Hα 6563 Hβ 4861 Hγ 4340 Paschen Series (Infra Red Region) Spectral Line Wavelength ( ˚ A) Pα 18751 Pβ 12818 Michael Papasimeon Hydrogenic Atoms April 16, 1998 8 / 33

9. Fine Structure The fine structure of the energy levels of

   hydrogenic atoms are due to relativistic effects and the spin of the electron which were not taken into account in the previous section. We can obtain an estimate on how much the energy levels are shifted, by using perturbation theory if we assume the the relativistic and spin effects are small. We can treat the Hamiltonian, energy eigenfunctions and energy levels as the unperturbed case and use first order perturbation theory for the perturbing components of the Hamiltonian. Michael Papasimeon Hydrogenic Atoms April 16, 1998 9 / 33

10. Perturbed Hamiltonian for Fine Structure The Schr¨ odinger equation is

    then of the following form: H0 + H1 + H2 + H3 ψnlm = Eψnlm (6) where H0 corresponds to the unperturbed Hamiltonian used in the previous section, and H 1 , H 2 and H 3 correspond to small perturbations involving relativistic corrections to the kinetic energy, the effect of spin-orbit coupling and the Darwin interaction. Michael Papasimeon Hydrogenic Atoms April 16, 1998 10 / 33

11. Modification to Unperturbed Hamiltonian The unperturbed Schr¨ odinger equation needs

    to be slightly modified in order to treat perturbing Hamiltonians which take the spin of the electron into account. The modified ‘unperturbed‘ equation is given by: H0ψ(0) nlml ms = E(0) n = ψ(0) nlml ms (7) where E(0) n are the Schr¨ odinger energy eigenvalues (with µ = m) and the zero order wave functions ψ(0) nlml ms are modified two component wave functions (also known as Pauli wave functions or spin-orbitals). Michael Papasimeon Hydrogenic Atoms April 16, 1998 11 / 33

12. Pauli Wave Functions or Spin-Orbitals ψ(0) nlml ms (q) =

    ψ(0) nlml (r)χ1 2 ,ml (8) The parameter q represents the combined spin and space coordinate, and χ1 2 ,ml are two component spinors (spin eigenfunctions for particle of spin one half). Michael Papasimeon Hydrogenic Atoms April 16, 1998 12 / 33

13. Normalised Spinors For spin-up (ms = +1/2) and spin-down (ms

    = −1/2), the normalised spinors are denoted by χ+ = 1 0 and χ− = 0 1 (9) Since the unperturbed Hamiltonian does not depend on the spin variable, the Pauli wavefunctions are separable in the spin and coordinate variables. To describe the state of an electron in a hydrogenic atom, we now have the four quantum number n, l, ml and ms. As a result of this, each of the unperturbed energy levels are En are 2n2 degenerate. Michael Papasimeon Hydrogenic Atoms April 16, 1998 13 / 33

14. Perturbed Energy Levels Finally the new perturbed energy levels to

    first order are given by E = E(0) n + ∆E1 + ∆E2 + ∆E3 (10) where ∆E (k) is the energy shift resulting from the k th perturbation. Michael Papasimeon Hydrogenic Atoms April 16, 1998 14 / 33

15. Relativistic Correction to the Kinetic Energy H1 = − p4

    8m3c2 (11) Since relativistic effects were not taken into account previously, the perturbing Hamiltonian H 1 represents the relativistic correction to the kinetic energy of the electron. Using first order perturbation theory the energy shift is given by ∆E1 = nlml ms −p4 8m3c2 nlml ms (12) ∆E1 = −En Z2α2 n2 3 4 − n l + 1 2 (13) Michael Papasimeon Hydrogenic Atoms April 16, 1998 15 / 33

16. Spin Orbit Interaction H2 = 1 2m2c2 1 r dV

    dr L · S (14) This perturbation corresponds to the shift in the energy as a result of the interaction between the internal spin of the electron and it’s orbital angular momentum as it orbits the nucleus. Since the potential V(r) = −Ze2/(4π 0r) for a hydrogenic atom, the perturbing Hamiltonian becomes H2 = 1 2m2c2 Ze2 4π 0r3 L · S (15) Michael Papasimeon Hydrogenic Atoms April 16, 1998 16 / 33

17. Energy Shift for Perturbed Hamiltonian The energy shift for this

    perturbing Hamiltonian using first order perturbation theory is ∆E2 = −En Z2α2 2nl(l + 1 2 )(l + 1) l, j = l + 1 2 −l − 1, j = l − 1 2 (16) Michael Papasimeon Hydrogenic Atoms April 16, 1998 17 / 33

18. Darwin Interaction H3 = π 2 2m2c2 Ze2 4π 0

    δ(r) (17) The Darwin term does not act on the spin variable and only applies when the orbital angular moment is zero (l = 0). The shift energy from the Darwin term is given by ∆E 3 = −En Z2α2 n , l = 0 (18) Michael Papasimeon Hydrogenic Atoms April 16, 1998 18 / 33

19. Fine Structure Energy Levels to First Order Based on the

    energy levels obtained for hydrogenic atoms from the Schr¨ odinger equation, and the energy shifts obtained from the three perturbation when relativistic and spin effects are taken into account we get Enj = En + ∆E1 + ∆E2 + ∆E3 . (19) Now subtracting from the binding energy E = mc2 − Enj E = mc2 1 − (Zα)2 2n2 − (Zα)4 2n3 n j + 1 2 − 3 4 (20) This result is valid if the perturbation is small, and therefore it begins to break down for hydrogenic atoms with large atomic numbers Z. Michael Papasimeon Hydrogenic Atoms April 16, 1998 19 / 33

20. Dirac Equation The equation which provides the correct energy eigenvalues

    and eigenstates for the fine structure of hydrogenic atoms is the Dirac equation. For a Hydrogenic atom that Dirac equation can be written as: cα · p + βmc2 − Ze2 4π 0r ψ = Eψ (21) where ψ is a 4-component spinor. Michael Papasimeon Hydrogenic Atoms April 16, 1998 20 / 33

21. Dirac Energy Levels The Dirac equation takes special relativistic effects

    and the spin of the electron (or any spin-1 2 particle) into account, and gives the following solutions for the energy eigenvalues for hydrogenic atoms. EDirac nj = mc2 1 + (Zα)2 n−j−1 2 + (j+1 2 )2 −(Zα)2 (22) Expanding the above equation in a series we obtain E = mc2 1 − (Zα)2 2n2 − (Zα)4 2n2 1 j + 1 2 − 3 4n − ... (23) This can be seen to agree with the result obtained previously using the perturbation theory for the first few terms. Michael Papasimeon Hydrogenic Atoms April 16, 1998 21 / 33

22. Hyperfine Structure Until now, the nucleus of hydrogenic atoms has

    been treated as a point charge, effectively of infinite mass. However, precise spectroscopic measurements of hydrogenic atoms reveal some very small effects on the energy levels which cannot be explained if the nucleus is treated in this way. These effects are known as hyperfine effects because they are much smaller then the fine structure effects predicted by the Dirac equation. The hyperfine effects can be grouped into two types. 1 Hyperfine structure effects give rise to splittings in energy levels 2 Isotope shifts slightly shift the energy levels and can usually be detected by observing the differences between two or more different isotopes. Michael Papasimeon Hydrogenic Atoms April 16, 1998 22 / 33

23. Electric Multipole Moments of the Nucleus Hyperfine structure effects arise

    from the electric multipole moments of the nucleus which can interact with the electromagnetic field produced at the nucleus by the electrons. The two main multipole moments are the magnetic dipole moment associated with the spin of the nucleus and the electric quadrupole moment due to the departure of the spherical charge distribution in the nucleus. Perturbation theory can be used to determine the shift in the energy these two multipole effects will have. Michael Papasimeon Hydrogenic Atoms April 16, 1998 23 / 33

24. Magnetic Dipole Interaction The perturbation which describes the interaction of

    the nuclear magnetic dipole moment consists of two expressions depending on the orbital angular momentum l. For the case of l = 0 we have HMD = 2µ0 4π gIµBµN 1 r3 G · I (24) where G = L − S + 3 (S · r)r r2 (25) and the total spin of the atom (nucleus and electron) is given by F = I + J. (26) For the case when l = 0, the perturbation is given by HMD = µ0 4π 2gIµBµN 8π 3 δ(r)S · I. (27) Michael Papasimeon Hydrogenic Atoms April 16, 1998 24 / 33

25. Electric Quadrupole Interaction The interaction Hamiltonian between the electric quadrupole

    moment of the nucleus and the electrostatic potential create by an electron at the nucleus is given (in atomic units) by HEQ = B 3 2 I · J(2I · J + 1) − I2J2 2I(2I − 1)j(2j − 1) (28) Michael Papasimeon Hydrogenic Atoms April 16, 1998 25 / 33

26. Hyperfine Spectrum The magnetic dipole and electric quadrupole interactions above

    correspond to a total hyperfine energy shift of ∆E = C 2 K + B 4 3 2 K(K + 1) − 2I(I + 1)j(j + 1) I(2I − 1)j(2j − 1) (29) where B is the quadrupole coupling constant given by B = Q ∂2V ∂z2 (30) and K = F(F + 1) − I(I + 1) − j(j + 1) (31) C = µ0 4π 2gIµBµN l(l + 1) j(j + 1) Z3 a3 µ n3l(l + l/2)(l + 1) (32) Michael Papasimeon Hydrogenic Atoms April 16, 1998 26 / 33

27. Energy Levels for Hydrogen Atom for n = 1 and

    n = 2 Bohr/ Schrodinger Hyperfine 2p(3/2) 2p(1/2) 2s(1/2) 2s(1/2) 2p(1/2) 2p(3/2) 1s(1/2) 1s(1/2) n = 2 n = 1 Dirac Lamb Shift F=2 F=1 F=1 F=0 F=1 F=0 F=1 F=0 Michael Papasimeon Hydrogenic Atoms April 16, 1998 27 / 33

28. 21cm Line of Atomic Hydrogen The energy level splitting diagram

    in the previous figure shows that the ground state of the hydrogen atom splits into two hyperfine levels with the total angular momentum of the atom being F = 0 and F = 1. The difference in energy between these two levels is 1420 MHz which corresponds to a wavelength of λ ≈ 21 cm. The probability of a transition occurring between these two levels is very low and occurs on average only once every few million years. However, there is a large amount of hydrogen gas in the galaxy allowing radio telescopes easily detect this 21 cm transition and therefore allow the mapping of hydrogen in the galaxy. Michael Papasimeon Hydrogenic Atoms April 16, 1998 28 / 33

29. Lamb Shift Investigation of the fine structure of hydrogenic atoms

    using spectroscopic techniques in the 1930’s showed that there were small differences between the observed spectra and the theoretical predictions made by the Dirac equation. For example, according to the Dirac equation the 2s1/2 and the 2p1/2 states coincide at the same energy level. Observations showed that the 2s1/2 was shifted slightly upwards by about 0.03 cm−1. A very accurate measurement of the shift was made in 1947 by Lamb and Retherford using microwave techniques to stimulate a direct radio-frequency transition between the 2s1/2 and the 2p1/2 levels. This small shift of energy levels became known as the Lamb shift. Michael Papasimeon Hydrogenic Atoms April 16, 1998 29 / 33

30. Visualising the Lamb Shift 8 MHz 1040 MHz 17 MHz

    2s(1/2), 2p(1/2) 2p(1/2) Dirac Levels Lamb Shifted Levels Michael Papasimeon Hydrogenic Atoms April 16, 1998 30 / 33

31. Quantum Electrodynamics The physics of the Lamb shift are described

    in the theory of quantum electrodynamics, in which radiative corrections to the Dirac equation are obtained by taking into account the interaction of a quantised electromagnetic field with an electron. The Lamb shift arises because of the zero point energy of a quantised electromagnetic field is non zero, similar to the zero point energy of a quantum harmonic oscillator. In a vacuum, fluctuations of the zero point energy of the quantised radiation field act on the electron. Michael Papasimeon Hydrogenic Atoms April 16, 1998 31 / 33

32. Quantum Electrodynamics (2) The effect of the electron is to

    cause it to oscillate rapidly about some equilibrium position. As a result of this oscillatory motion, the electron does not appear to be point charge – instead the electron charge is slightly smeared at in a sphere of some small radius. When the electron is bound by an electric field as it is in an atom, the potential it experiences is slightly different to that experienced by the electron in it’s mean position. Therefore electrons which are most sensitive to short distance modifications such as those in the ground state are raised in energy with respect to other states to which the shift is much smaller. Michael Papasimeon Hydrogenic Atoms April 16, 1998 32 / 33

33. References 1 Physics of Atoms and Molecules, Bransden and Joachain

    2 Quantum Mechanics of One- and Two-Electron Atoms, Bethe and Salpeter 3 Intermediate Quantum Mechanics, Bethe 4 Advanced Quantum Mechanics, Sakurai 5 The Spectrum of Atomic Hydrogen - Advances, Series 6 Quantum Mechanics, Merzbacher 7 Modern Physics, Serway, Moses and Moyer 8 WikiMedia Commons Hydrogen Spectrum http://commons.wikimedia.org/wiki/File:Hydrogen spectrum.svg Michael Papasimeon Hydrogenic Atoms April 16, 1998 33 / 33