Upgrade to Pro — share decks privately, control downloads, hide ads and more …

Gravitational Lensing by Point Masses

Gravitational Lensing by Point Masses

These slides are from a presentation on Gravitational Lensing which is based on a paper I wrote for an undergraduate Computational Physics class which I took in 1998. The paper was converted to an IEEE LaTeX template and some of the key concepts of the paper were turned into LaTeX/Beamer presentation which has been uploaded here.

Michael Papasimeon

October 29, 1998
Tweet

More Decks by Michael Papasimeon

Other Decks in Science

Transcript

  1. Gravitational Lensing by Point Masses Michael Papasimeon 29 October 1998

    Michael Papasimeon Gravitational Lensing 29 October 1998 1 / 34
  2. The Lens Equation The angular deflection α of a gravitational

    lense is given by α = 4GM c2ξ (1) where M = mass of the deflecting object G = gravitational constant c = speed of light ξ = impact radius of the incoming photon α = deflection angle Michael Papasimeon Gravitational Lensing 29 October 1998 3 / 34
  3. Angular Deflection of a Photon ξ α Mass M Star

    Observer Michael Papasimeon Gravitational Lensing 29 October 1998 4 / 34
  4. Deflecting Mass The deflecting mass may be viewed as an

    optical thin lens, made up of a two dimensional mass distribution. M = R2 Σ(ξ ) ξ − ξ |ξ − ξ |2 d2ξ (2) where Σ = surface density R2 = surface area If the deflecting mass, is perfectly symmetric, the deflection angle becomes α = 4GM(< ξ)ξ c2|ξ|2 (3) Michael Papasimeon Gravitational Lensing 29 October 1998 5 / 34
  5. The Lens Equation The lens equation is ψDos + αDds

    = βDos (4) It is often the case in many gravitational lensing problems that the images form do not depend on the distances between source, observer and deflector directly. Rather a specific ratio of these distances is the quantity which needs to be considered. This is known as the effective distance D and is defined as: D = Dod Dds Dos (5) Michael Papasimeon Gravitational Lensing 29 October 1998 6 / 34
  6. Setup for the Gravitational Lens Equation Dds Dod ξ α

    α β Observer Source Image Deflector ^ ψ Michael Papasimeon Gravitational Lensing 29 October 1998 7 / 34
  7. Einstein Ring If a distant star is in perfect alignment

    with a point mass gravitational lens and an observer, the light from the distant star is lensed perfectly symmetrically forming a ring image of the star known as an Einstein ring. The radius of the Einstein ring is given by θE = 4GM c2 Dds Dod Dos (6) If however there isn’t a perfect alignment, for a point mass two images are produced for each point on the source plane. The angular positions at which these images is given by: θ± = ξ Dod = β 2 ± β2 + 4θ2 E (7) where β is the angular position of the source as shown in figure 3. The magnification of each of the images is given by µ± = 1 4 y y2 + 4 + y2 + 4 y ± 2 (8) where the source and image angles have been scaled such that y = ψ/α0 and x = α/α0. Michael Papasimeon Gravitational Lensing 29 October 1998 8 / 34
  8. Reformulating the Lens Equation Using this notation the lens equation

    can be rewritten as the scaled lens equation given by y = x − α(x). (9) The vector notation used represents the coordinate in a cartesian plane. Therefore y = (y1, y2) is a coordinate in the source plane and x = (x1, x2) is a coordinate in the deflecting plane. Michael Papasimeon Gravitational Lensing 29 October 1998 9 / 34
  9. Complex Notation This can also be written using complex number

    notation. A position in deflecting plane can be denoted as z = x1 + ix2, and a position in the source plane as zs = y1 + iy2. The magnification is given by: µ(x) = 1 detA(x) (10) where detA(x) is the Jacobian determinant of the Hessian matrix given by A(x) = ∂y ∂x (11) Michael Papasimeon Gravitational Lensing 29 October 1998 10 / 34
  10. Critical Curves and Caustics Critical curves are the set of

    all points in the deflection plane where A(x) = 0. The corresponding curves in the source plane (obtained from the lens equation) are known as caustics. Critical curves are where the gravitational lens infinitely magnifies the light passing through that point. Source plane caustics are the pre-image of the critical curves. Any light emitted near a caustic will be greatly magnified as it passes through the lens. Michael Papasimeon Gravitational Lensing 29 October 1998 11 / 34
  11. The Chang-Refsdal Lens The Chang-Refsdal lens model describes gravitational lensing

    using a modification of the point mass model. This model says that when a source crosses a fold caustic the lensing is due to a point mass but with an additional external shear applied. The corresponding lens equation for the Chang-Refsdal model is: y = 1 + γ 0 0 1 − γ x − x |x|2 (12) This can also be written in the complex notation as zs = z + γ¯ z − ¯ z , where γ is a constant determining the amount shear. = ( κs 1−κc ), where κs is the density of compact objects such as stars and κc is the surface density of continuously distributed matter. Michael Papasimeon Gravitational Lensing 29 October 1998 12 / 34
  12. The Effects of Distance on Gravitational Lensing The Dyer-Roeder equation

    is given by: (z + 1)(Ωz + 1) d2D dz2 + 7 2 Ωz + 1 2 Ω + 3 dD dz + 3 2 ˜ αΩD = 0 (13) This relates the angular diameter distance of a lensing system with the redshift z of the source object. Ω is the ratio of the mean mass density to the critical density of the universe and ˜ α is the clumpiness parameter, which determines the amount of matter between the source and the observer. Michael Papasimeon Gravitational Lensing 29 October 1998 13 / 34
  13. Initial Conditions for Dyer-Roeder Equation The initial conditions of the

    Dyer-Roeder equation are: Dii = 0 (14) dDij dz zj =zi = sgn(zj − zi) (zi + 1)2 √ Ωzi + 1 (15) The Dyer-Roeder equation needs to be solved for three different cases. 1 Ω = 0 (DI) 2 Ω = 1, ˜ α = 1 (DII) 3 Ω = 1, ˜ α = 0 (DIII) Michael Papasimeon Gravitational Lensing 29 October 1998 14 / 34
  14. Solving the Dyer-Roeder Equation This leads to three different equations

    which need to be solved. (z + 1) d2D dz2 + 3 dD dz = 0 (16) (z + 1)2 d2D dz2 + 7 2 (z + 1) dD dz + 3 2 D = 0 (17) (z + 1)2 d2D dz2 + 7 2 (z + 1) dD dz = 0 (18) Michael Papasimeon Gravitational Lensing 29 October 1998 15 / 34
  15. Computational Solution to the Dyer-Roeder Equation A FORTRAN program was

    written to numerically solve these equations. The algorithm used to solve these equation numerically was the Runge-Kutta-Nystr¨ om method. This method is a fourth order algorithm which is a general form of the standard Runge-Kutta method, used for solving second order ordinary differential equations. The equations were integrated from z = 0 to z = 10. The dimming factor (DII/DIII)2 was determined and plotted as a function of redshift z. Michael Papasimeon Gravitational Lensing 29 October 1998 16 / 34
  16. Solutions to the Dyer-Roeder Equation We solve the Dyer-Roeder equation

    for the three different cosmologies resulting in three solutions for the angular diameter distance D. DI d1.dat (The top curve) DII d2.dat (The bottom curve) DIII d3.dat (The centre curve) 0 0.05 0.1 0.15 0.2 0.25 0.3 0.35 0.4 0.45 0.5 0 1 2 3 4 5 6 7 8 9 10 Angular Diameter Distance D Source Redshift z ’d1.dat’ ’d2.dat’ ’d3.dat’ Michael Papasimeon Gravitational Lensing 29 October 1998 17 / 34
  17. Increasing Redshift According to the big bang model of the

    universe, objects with large redshifts are further away. Hence the results of solving the Dyer-Roeder equation for the cases (1 and 3) when the “clumpiness” parameter ˜ α is ignored the angular diameter distance D increases as the redshift increases. In both cases we get asymptoting values: lim z→∞ DI(z) = 0.5 (19) lim z→∞ DII(z) = 0.4 (20) Michael Papasimeon Gravitational Lensing 29 October 1998 18 / 34
  18. Dimming factor against source redshift 0 1000 2000 3000 4000

    5000 6000 7000 8000 0 10 20 30 40 50 60 70 80 90 100 Dimming Factor (D2/D3)**2 Source Redshift z ’dim.dat’ Michael Papasimeon Gravitational Lensing 29 October 1998 19 / 34
  19. Lensing an Extended Source by a Point Mass Lensing Algorithm

    1: procedure LENSE 2: img ← load image() 3: xc, yc ← find centre(img) 4: θE ← calc einstein radius() 5: for c ∈ img.coordinates do 6: bx , by ← calc location lensing body() 7: β ← impact radius() 8: calc angle for each quadrant() 9: θ± ← calc new angles() 10: c ← calc new deflected coordinate() 11: end for 12: save image(img) 13: end procedure Michael Papasimeon Gravitational Lensing 29 October 1998 20 / 34
  20. Lensing Images A number of different images were used in

    the simulation. Two were used for testing purposes and to observe the effect, and three were images of astronomical interest. The images used include: A human face The starship Enterprise The Andromeda Galaxy The Milky Way The Pleiades Star Cluster In all cases the distance ratio used was D = 1 and just the mass was varied. This is because when calculating the Einstein radius, the quantity DM appears as follows: θE = 4GMD c2 (21) Michael Papasimeon Gravitational Lensing 29 October 1998 21 / 34
  21. Gravitational lensing of image of a human face by a

    mass M = 5 × 1030 kg Michael Papasimeon Gravitational Lensing 29 October 1998 22 / 34
  22. Gravitational lensing of an image of the starship Enterprise Michael

    Papasimeon Gravitational Lensing 29 October 1998 23 / 34
  23. Gravitational Lensing of the Andromeda Galaxy M = 0kg M

    = 1 × 1030 kg, D = 1 M = 1 × 1031 kg, D = 1 M = 4 × 1031 kg, D = 1 Michael Papasimeon Gravitational Lensing 29 October 1998 24 / 34
  24. Caustics for the Chang-Refsdal Lens det A = 1 −

    γ + ¯ z2 γ + ¯ z2 = 0 (22) . Using complex polar coordinates letting z = x cos φ + ix sin φ we get x4(1 − γ2) − 2γ x2(cos2 φ − sin2 φ) − 1 = 0 (23) The equation can be parameterised by letting: λ = cos2 φ − sin2 φ u = x2 giving u2(1 − γ2) − 2γ λu − 1 = 0. (24) Michael Papasimeon Gravitational Lensing 29 October 1998 27 / 34
  25. Caustics for the Change-Refsdal Lens (continued) Solving this quadratic we

    obtain: u = γ λ ± γ2(λ2 − 1) + 1 (1 − γ2) (25) For a given values of γ, and for 0 < φ < 2π the program calculates u and then x. The (x, y) coordinates for the caustic curve is then given by (x cos φ, x sin φ). The corresponding caustics are given by: y1 = (1 + γ)x − x 1 + λ 2 (26) y2 = (1 − γ)x − x 1 − λ 2 (27) Michael Papasimeon Gravitational Lensing 29 October 1998 28 / 34
  26. Selecting Values for and γ In the program a value

    of = 0.5 was chosen. Values of gamma were chosen for the four representative regions in which caustics are found. The four regions are: γ < −1 −1 < γ < 0 0 < γ < 1 γ > 1 The four values of γ selected are: γ = −1.3 γ = −0.4 γ = +0.8 γ = +1.6 Michael Papasimeon Gravitational Lensing 29 October 1998 29 / 34
  27. Critical curves and caustics for γ = −1.3 -0.8 -0.6

    -0.4 -0.2 0 0.2 0.4 0.6 0.8 -2 -1.5 -1 -0.5 0 0.5 1 1.5 2 "neg1.3.critical.dat" -15 -10 -5 0 5 10 15 20 25 -25 -20 -15 -10 -5 0 5 10 15 20 25 "neg1.3.caustic.dat" Michael Papasimeon Gravitational Lensing 29 October 1998 30 / 34
  28. Critical curves and caustics for γ = −0.4 -1.5 -1

    -0.5 0 0.5 1 1.5 -1 -0.8 -0.6 -0.4 -0.2 0 0.2 0.4 0.6 0.8 1 "neg0.4.critical.dat" -1.5 -1 -0.5 0 0.5 1 1.5 -0.2 -0.15 -0.1 -0.05 0 0.05 0.1 0.15 0.2 "neg0.4.caustic.dat" Michael Papasimeon Gravitational Lensing 29 October 1998 31 / 34
  29. Critical curves and caustics for γ = 0.8 -1.5 -1

    -0.5 0 0.5 1 1.5 -2 -1.5 -1 -0.5 0 0.5 1 1.5 2 "pos0.8.critical.dat" -0.15 -0.1 -0.05 0 0.05 0.1 0.15 -4 -3 -2 -1 0 1 2 3 4 "pos0.8.caustic.dat" Michael Papasimeon Gravitational Lensing 29 October 1998 32 / 34
  30. Critical curves and caustics for γ = 1.6 -1.5 -1

    -0.5 0 0.5 1 1.5 -0.4 -0.3 -0.2 -0.1 0 0.1 0.2 0.3 0.4 "pos1.6.critical.dat" -25 -20 -15 -10 -5 0 5 10 15 20 25 -20 -15 -10 -5 0 5 10 15 20 25 "pos1.6.caustic.dat" Michael Papasimeon Gravitational Lensing 29 October 1998 33 / 34