High Energy Astrophysics High energy astrophysics typically deals with x-rays and higher energy...
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High Energy Astrophysics h energy astrophysics typically deals with x-rays a er energy radiation. It also deals with high energy rinos and other particles such as protons, electron gh energy radiation is produced by objects at high atures and/or relativistic particles. 1 ev = 10,000 K, 1 kev = 10 7 K • • • usually requires compact objects such as white dwa ron stars or blackholes with deep gravitational pot V esp =(2GM/R) 1/2 approaching c Or R not much greater than the Schwarzschild radiu GM/c 2 (2.95 km for a solar mass object).
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Transcript of High Energy Astrophysics High energy astrophysics typically deals with x-rays and higher energy...
High Energy Astrophysics
High energy astrophysics typically deals with x-rays and higher energy radiation. It also deals with high energy
neutrinos and other particles such as protons, electrons, positrons etc.
High energy radiation is produced by objects at high temperatures and/or relativistic particles.
1 ev = 10,000 K, 1 kev = 107 K
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This usually requires compact objects such as white dwarfs, neutron stars or blackholes with deep gravitational potential.
Vesp=(2GM/R)1/2 approaching c
Or R not much greater than the Schwarzschild radius: 2 GM/c2 (2.95 km for a solar mass object).
X-ray astronomy: 0.1 to 100 kev
Gamma-ray astronomy: >100 kev.
E=h \nu = k T ==> x-rays probe 106 -- 109 K and gamma-rays > 109 K
Eddington Luminosity: 1.3x1038 erg/s for 1 Mo.
Optically thick blackbody radiation in x-rayrequires a compact object!
(derive the Eddington limit)
T as a function of object mass, radius (in units of Schwarzschild radius) and Luminosity (in units of Eddington luminosity), is given by:
T ~ 7 kev (L/L_Edd)^{1/4} (R/R_s)^{-1/2} (M/M_sun)^{-1/4}
Brief Property and History of Compact Objects
White dwarfs: R~10,000 km, Vesc~0.02 c, density~ 106 g/cc
(Nuclear reaction is more efficient source of energythan the PE release of in-falling gas on WDs).
1. 1914: Adams-- Sirius B has M~ 1Mo, T~ 8000 K, R~10,000km2. 1925: Adams confirmed M & R by measuring gravitational
redshift -- z ~ GM/(R c2)=0.0003.
3. 1926: F-D statistics discovered. Fowler applied it to model WDs.
4. 1930: Chandrasekhar: WD model including relativity; mass limit.
5. 1983: Nobel prize to Chandrasekhar.
Neutron Stars1. 1931: Chadwick --discovers neutrons. 2. 1934:Baade & Zwicky suggested neutron-stars, and
postulated their formation in supernovae.
3. 1967: Hewish, Bell et al. Discover radio pulsars.
4. 1968: Gold proposed rotating NS model.5. 1974: Nobel prize to Ryle (aperture synthesis)
Hewish (pulsars).
6. 1975: Hulse & Taylor discover binary pulsar PSR 1913-16.
7. 1993: Nobel prize to Hulse & Taylor.
Neutron stars: R~15 km, Vesc~0.32 c, density~ 1014 g/cc
(Nuclear reaction is much less efficient source of energythan the PE release of in-falling gas on NSs).
Black Holes
1795: Laplace noted the possibility of light not being able to escape.
1915: Einstein’s theory of general relativity.
1916: Schwarzschild -- metric for a spherical object
1963: Kerr --metric for a spinning BH.
1972: Discovery of Cyg X-1
1995: Miyoshi et al. -- NGC 4258.
1997: Eckart & Genzel -- (Sgr A*) Galactic center.
2002: Nobel prize in physics to Giacconi (x-ray astronomy).
Schwarzschild radius = 2.95 km M/Mo
Efficiency of energy production 6% to 42%.
Summary of last lecture
1. Derivation of the Eddington limit.
2. We showed that bright sources of high energyphotons are typically compact objects suchas WD, NS or BH.
High speed, strong, shocks are another way of generating high energy photons; however
high speed shocks are usually produced when compact objects form eg. SNe, GRB etc.
(an exception is x-rays from clusters.)
(1 Ao = 12.5 kev)
(SOHO) at 171 A = 74 ev
EUV picture of the Sun
Corona & severalActive regions
are visible
Coronal luminosity:~ 1026 erg/s
SOHO
EUV picture of the Sun at 195 A = 65 ev
from
Corona, active regionsand a flare is visible
at 195 A = 65 ev
QuickTime™ and aGIF decompressor
are needed to see this picture.
Crab nebula
Blue: x-ray
Red: optical
Green:radio
Luminosity ~ 1038 erg/s(mostly x-ray & gamma)
Synchrotron radiation:(linear polarization of 9%averaged over nebula).
Electrons with energy > 1014 ev are needed for emission at 10 kev;lifetime for these e’s < 1 year. So electrons must be injected
continuously & not come from SNe.
(Plerion)
SN remnant: Cas A (3-70 kev; Chandra)
Age 300 yr (1670 AD)
SNe II remnant
Mass of x-ray gas10-15 solar mass.
(Plerion)
X-ray luminosity:3.8x1036 erg/s
Pulsar wind nebula G292(Chandra 3-80 kev)(Plerion)
SN remnant G11.2-0.3 in x-ray (Chandra)
X-ray luminosity:~ 1036 erg/s.
The radiation is produced by shock heated gas at ~ 109 Kvia bremsstrahlung.
Note the bright (blue)Pulsar nebula at the Center.
Produced in SN of 386 AD
AGN jet from the quasar GB 1508+5714 (distance 4Gpc)
Chandra x-ray obs.
(x-ray produced by IC of CMB-photons with jet e-s)
Obs. jet size~30 kpc
Cen A
HST & 6 cm VLA
VLA: 6 cm
(distance ~ 2.5 Mpc)
Radio lobe size ~ 200 kpc!
The radio lobes are fed by relativistic jets; we see onlyone sided jet due to relativistic beaming.
Stephan’s Quintet
Blue:Chadra x-ray
SDSS optical
Yellow:
Compact group of interacting galaxies. Gas is stipped and shock heated to 6 million K produces x-rays.
F is a foreground galaxy. So thecluster (A, B, D & E) is in fact a quartet.
Cluster x-ray & optical
Chandra x-ray; ~ 2 kevHST - optical image
(note lensing of background gals)
Abel -2390.5 Gpc
MS2137.3-2353(1 Gpc)
SN remnant G11.2-0.3
M87 jet
