Homework 9 due Nov. 26 (after Thanksgiving)

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Transcription:

Homework 9 due Nov. 26 (after Thanksgiving) [CO 17.6 parts (a), (b)] [16.6 1 st ed., parts (a), (b)] Derive the deflection of the light ray passing a massive object. Note that your answer will come out a factor of two smaller than Eq. 28.20 [26.15 1 st ed.] because you are only asked to consider the term affecting the space-like part of the Schwarzschild metric. The time-like part is also affected (this is the answer to part c of this problem. Special offer: I have placed copious hints for how to solve this problem on the course web site. You re in luck I don t know how to set up a secure web site requiring credit card payments, so these hints are absolutely free of charge. But give the problem a try without the hints as a starter. [CO 28.15] [26.16 1 st ed.] Pay attention to the hint given with the problem. And remember the following oldies but goodies: and the law of sines: [CO 28.16] [26.17 1 st ed.]

Mass/Luminosity Dark Matter so far Local stellar luminosity function: M/L = 0.67 Our Galaxy, at larger scales: Oort limit: M/L ~ 2.7 Slice through disk (Bahcall & Soniera) ~ 5 Rotation curve > 30 Escape speed > 30 Pop II dynamics (glob. clusters, etc.) ~ 27 Magellanic stream > 80 Local Group timing 100 X-ray halo of M87 > 750 Groups of galaxies 200h

Virial Theorem for Clusters Galaxy clusters fair samples of the universe. Coma is closest relaxed cluster Original mass measurement was by Zwicky (1933). Measure n(r), σ v (r) n(r) = # of galaxies, σ v (r) = vel. Dispersion Fit to models based on collisionless Boltzmann eq. ~ isothermal, non-spherical. Coma: M = 2x10 15 M M/L = 360h (+0, -180h) Perseus: M/L = 600h Determining membership

X-ray emitting gas in clusters Hydra A - Chandra Hydra A - Optical

X-ray emitting gas in clusters [CO fig. 27.17] Same method as used for x-rays from individual galaxies ==> M/L ~ 180h gas is important mass component of cluster emission by thermal bremsstrahlung (free-free). L X ~ 10 43-10 45 erg/s (5x10 44 erg/s for Coma) amplitude freq. distr. Hz -1,T = hν M gas = (4/3) πr 3 n e m H = 3x10 14 M M stars = (M/L) Local L V = 2x10 13 M Hydra A - Chandra Hydra A - Optical

Gravitational Lensing Foreground cluster distorts images of numerous background galaxies. Use to determine total mass of foreground cluster. Shows that 85% of mass is Dark Matter.

Gravitational Lensing R-W metric [CO 17.28]

Gravitational Lenses 1938+666 HST radio The Einstein Cross Galaxy at center causes 4 images of same quasar.

Gravitational Lens Simulator Blandford & Narayan 1986 ApJ, 310, 568 Source Observer Reflective, stretchy membrane Lensing Mass

Gravitational Lensing by a Point Mass [CO Sect. 28.4] (28.20) (28.21) (28.24)

Effect of Lensing on Flux See Refsdal (1964) MNRAS 128, 295 Max amplification when β = 0 ~ θ E /α S Not aligned β /θ E F 1 /F N F 2 /F N F T /F N β = θ E F = F N Close alignment

Point mass forms two images (or ring) β

Caustics & Catastrophes

Lensing by a Transparent Mass Distribution Caustic Surfaces: Number of images changes by 2 each time a caustic is crossed always an odd number (if lens is transparent). Rays: Wave fronts:

θ >> θ E θ < θ E 1938+666 HST radio The Einstein Cross

Weak (and not-so-weak) Lensing Abell 2218 Foreground cluster distorts images of numerous background galaxies. Use to determine total mass of foreground cluster. Shows that 85% of mass is Dark Matter.

Using caustics to search for high-redshift background galaxies

The Remarkable Case of CL0024+1654 Single distant blue galaxy z ~ 1.2 1.8 Lensed by foreground cluster z = 0.39 8 different grav. images of blue galaxy. Allows detailed analysis of mass distribution in cluster. 83% of mass is non-luminous Dark Matter. M/L = 270h (390h after allowing for stellar evolution to z = 0)

The Remarkable Case of CL0024+1654 Single distant blue galaxy z ~ 1.2 1.8 Lensed by foreground cluster z = 0.39 8 different grav. images of blue galaxy. Allows detailed analysis of mass distribution in cluster. 83% of mass is non-luminous Dark Matter. M/L = 270h (390h after allowing for stellar evolution to z = 0)

The Remarkable Case of CL0024+1654 Single distant blue galaxy. Lensed by foreground cluster. 8 different images. Allows detailed analysis of mass distribution in cluster. 83% of mass is non-luminous Dark Matter.

Dark Matter Galaxy clusters, typical values 85% Dark Matter 15% Normal Matter 14% hot intergalactic gas ~1% stars in galaxies Mass/Luminosity Local stellar luminosity function: M/L = 0.67 Our Galaxy, at larger scales: Oort limit: M/L ~ 2.7 Slice through disk (Bahcall & Soniera) ~ 5 Rotation curve > 30 Escape speed > 30 Pop II dynamics (glob. clusters, etc.) ~ 27 Magellanic stream > 80 Local Group timing 100 X-ray halo of M87 > 750 Groups of galaxies 200h Clusters of galaxies 400h Average for universe: 85% dark matter 15% normal matter

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