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Galaxies in the XMMNewton and Chandra era

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Title: Galaxies in the XMMNewton and Chandra era

1
Galaxies in the XMM-Newton and Chandra era

Antonis Georgakakis
Imperial College

2
Outline

Overview of galaxies at X-rays
Emission components (e.g. XRBs, SNR, hot gas)
Astrophysical significance
Emission mechanisms
Cosmological significance

X-ray Astronomy Summer School, Athens 2006
3
Galaxies at optical Hubble sequence

Ellipticals
smooth profiles
old stars
Spirals
spiral arms
young stars
Lenticulars
smooth profile spiral structure
Irregulars
amorphous
young stars

X-ray Astronomy Summer School, Athens 2006
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Emission components

X-ray binaries
Supernovae remnants
Hot gas
Stellar coronae

Accretion of material from primary to compact
secondary (black hole or neutron star) infalling
material heats up to 106K giving off
X-rays Low-mass X-ray binaries primary mass
similar or lower to that of the Sun, slow
evolution High-mass X-ray binaries primary mass
gt3M?, fast evolution timescale Major contributor
to integrated X-ray emission of our Galaxy (50)
X-ray Astronomy Summer School, Athens 2006
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Emission components

X-ray binaries
Supernovae remnants
Hot gas
Stellar coronae

Explosion produces shock wave that accelerates
electrons and heats up material X-rays due to
thermal, synchrotron and bremsstrahlung
radiation. However, small contribution to total
X-ray emission of Galaxy (lt1-2)
Cas-A, T5?106K
X-ray Astronomy Summer School, Athens 2006
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Emission components

X-ray binaries
Supernovae remnants
Hot gas
Stellar coronae

Gas heated by SN explosions trapped in galaxy
potential well. Relativisitc electrons produce
X-rays by bremsstrahlung Major contribution to
total X-ray emission of galaxies (50-100)
X-ray Astronomy Summer School, Athens 2006
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Emission components

X-ray binaries
Supernovae remnants
Hot gas
Stellar coronae

Like the Sun, most stars have atmosphere of hot
plasma (T106K) thermal X-ray emission
However, minor contribution to overall Galaxy
X-ray emission (lt1-2)
X-ray Astronomy Summer School, Athens 2006
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Galaxies at X-rays does it worth it?

X-rays represent a tiny fraction of the energy
output of galaxies
e.g. Arp 220
most of the energy at the infrared
X-rays 5dex lower flux!
This is unlike AGN (e.g. NGC 5548) where X-rays a
dominant component

LMC
X-ray Astronomy Summer School, Athens 2006
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Galaxies at X-rays why important?

Hot gas component
Metal enrichment
formation history of ellipticals
Binary star population
formation evolution
link to star-formation

X-ray Astronomy Summer School, Athens 2006
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Galaxies at X-rays why important?

Hot gas component
Metal enrichment
formation history of ellipticals
Binary star population
formation evolution
link to star-formation

Antennae
Credit NASA/CXC/SAO/G. Fabbiano et al.
X-ray Astronomy Summer School, Athens 2006
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Galaxies at X-rays why important?
NGC 1700 merger remnant

Hot gas component
Metal enrichment
formation history of ellipticals
Binary star population
formation evolution
link to star-formation

Credit NASA/Ohio U./T.Statler et al.
X-ray Astronomy Summer School, Athens 2006
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Galaxies at X-rays why important?
Credit NASA/UMass/Z.Li Q.D.Wang

Hot gas component
Metal enrichment
formation history of ellipticals
Binary star population
formation evolution
link to star-formation

Point sources (X-ray binaries) Diffuse hot gas
(106-107K)
X-ray Astronomy Summer School, Athens 2006
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Galaxy gallery

Point sources (mostly XRBs) follow spiral
structure (link to star-formation)
Ultra luminous X-ray sources 10-1000 X-ray power
compared to typical X-ray binaries.
Accretion on intermediate mass black holes,
100-104M?.
How such massive compact objects created?

Credit X-ray NASA/CXC/U. of Michigan/J.Liu et
al. Optical NOAO/AURA/NSF/T.Boroson
X-ray Astronomy Summer School, Athens 2006
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Galaxy gallery
Antennae

Galaxy fountains
Bubble of warm (104K red) and hot (107K blue)
gas blown out of the galaxy.
SN explosions or AGN activity
Metal enrichment of interstellar/intergalactic
medium
Regulation of SF/AGN activity by depleting fule
(cold gas) from galaxy centres

NGC 3979 superwind
Credit NASA/CXC/STScI/U.North Carolina/G.Cecil
X-ray Astronomy Summer School, Athens 2006
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Galaxy gallery

Ellipticals
X-rays dominated by diffuse emission
Hot gas distribution inhomogeneous (unlike
optical)
Some stirring mechanism in operation possible
periodic AGN activity

Credit X-ray NASA/CXC/U. Ohio/T.Statler
S.Diehl
X-ray Astronomy Summer School, Athens 2006
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Summary I

Galaxies are faint X-ray sources BUT
X-rays unique diagnostic of galaxies
the only observational tool to study stellar
binaries
direct census of metal enrichment
information on galaxy formation/evolution

X-ray Astronomy Summer School, Athens 2006
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Binary star orbits

Roche lobes the volume around a star in a binary
system in which, if you were to release a
particle, it would fall back onto the surface of
that star.
L1 inner Lagrangian point where the gravity from
the two stars is equal. Mass is transferred from
one star to the other through L1.

X-ray Astronomy Summer School, Athens 2006
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X-ray binaries accretion

Transfer of mass occur via
Roche-lobe overflow through L1. An accretion disk
is formed.
capture of the stellar wind of the primary. An
accretion disk may form.

X-ray Astronomy Summer School, Athens 2006
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X-ray binaries accretion

Spherical accretion radiation pressure cannot
exceed gravitational pull.
Upper limit in luminosity, LEddington. Scales
with mass of accreting source.

LEddington 1.3?1038 (M/M?) erg/s
X-ray Astronomy Summer School, Athens 2006
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X-ray binary luminosities

X-ray binaries typically have LXltlt1038erg/s
LMXRBs
Flat distribution at faint-end
max luminosities 1038-1039erg/s.
HMXRBs
Power-law distribution
Max LX 1040erg/s, i.e. brighter than the Milky
Way!!!

Gilfanov 2004
X-ray Astronomy Summer School, Athens 2006
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Ultra-Luminous X-ray Sources
M74

Massive stellar source, M100M?, intermediate
mass black holes
Non-spherical accretion
Collimated emission, i.e. in a funnel.

X-ray Astronomy Summer School, Athens 2006
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X-ray binaries accretion
L2?r2?T4, TBB( L / 2?r2? )1/4, Assuming the
Eddinghton limit kTBB6.7?(M/M?)
(R/km)-21/4 Using typical values for accreting
sources NS 1.4M?, R10km ?kTBB2keV WD 3M?,
R5000km ?kTBB0.1keV BH R2GM/c2
?kTBB1keV(M/M?)-1/4

Black-body temperature, TBB typical temperature
of the source if it radiated as black body.
For typical values of compact accreting sources
(white dwarfs, neutron stars and black holes)
black body radiation peaks at the X-ray regime.

X-ray Astronomy Summer School, Athens 2006
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X-ray binary spectra

Complex X-ray spectra
Power-law component with G1-2 (hot corona
Compton scattering)
Black-body component at soft energies (lt1keV
accretion disk)
Also variability, high/low states, absorption etc

X-ray Astronomy Summer School, Athens 2006
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X-ray binary lifetimes
Evolution timescale time it takes for the star
to radiate the energy produced by H?He
thermonuclear reactions tlifeMc2/L, where M
mass of the star and L its luminosity. Empirical
relation between stellar mass and
luminosity LM3.5, combining the two
tlifeM?2.5, 1M? tlife1010yr 10M? tlife107yr
X-ray Astronomy Summer School, Athens 2006
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X-ray binary lifetimes
Evolution timescale time it takes for the star
to radiate the energy produced by H?He
thermonuclear reactions tlifeMc2/L, where M
mass of the star and L its luminosity. Empirical
relation between stellar mass and
luminosity LM3.5, combining the two
tlifeM?2.5, 1M? tlife1010yr 10M? tlife107yr

HMXRBs
primary massive star (gt2M?)
short-lived (107yr)
measure instantaneous star-formation rate
LMXRBs
primary low-mass star (1M?)
long lived (109yr)
measure star-formation integrated over the
lifetime of the galaxy, i.e. total stellar mass.

X-ray Astronomy Summer School, Athens 2006
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Summary II

X-ray binaries X-ray emission via accretion on a
compact object
HMXRBs short-lived, luminous, linked to
star-formation
LMXRBs long-lived, less luminous, linked to
stellar mass

X-ray Astronomy Summer School, Athens 2006
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Hot gas

Gas origin
mass ejected by old stars
gas falling back on the galaxy
Gas heating mechanism
shock heating
Supernovae
AGN feedback?

X-ray Astronomy Summer School, Athens 2006
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Hot gas Bremsstrahlung

Bremsstrahlung or braking radiation emitted by a
charged particle when accelerating in electric
field.
In the case of X-rays, e- in Coulomb collision
charge of Z protons
The resulting spectrum is flat with an upper
cutoff wcut, related to the interaction time, Dt
v/b, or interaction frequency w 1/Dt b/v

X-ray Astronomy Summer School, Athens 2006
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Hot gas thermal Bremsstrahlung

In astrophysically interesting cases, electrons
have velocity distribution.
In the case of plasma with uniform temperature T,
Maxwell distribution
Thermal Bremsstrahlung falls off exponentially at
high energies
Hot gas is radiatively cooling via Bremsstrahlung
?T0.5 and ?np
e.g. ellipticals np0.1cm-3 and T107K
tcool3?108yr (cooling problem)
spirals np0.1cm-3 and T106K
tcool8?107yr

X-ray Astronomy Summer School, Athens 2006
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X-ray spectra of galaxies

Elliptical galaxy NGC 4649
Two temperature hot gas components
T8?106 2?107K
85 of LX
Power-law, G1.8
stellar sources (e.g. binaries)
15 of the luminosity

Randall et al. 2006
X-ray Astronomy Summer School, Athens 2006
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X-ray spectra of galaxies

Starburst galaxy NGC 3310
Two temperature hot gas components
T3?106 7?106K
25 of the 0.3-10keV LX
Power-law, G1.8
stellar sources (e.g. binaries)
75 of the 0.3-10keV luminosity

Jenkins et al. 2004
X-ray Astronomy Summer School, Athens 2006
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X-ray emission and star-formation

Linear relation between X-ray luminosity and
star-formation indicators (e.g. far-infrared
luminosity) for spirals.
X-ray emission can be used as a census of the
star-formation rate (SFR) in late type galaxies.
X-ray/SFR correlation is driven by short-lived
HMXRB population

Ranalli et al. 2003
X-ray Astronomy Summer School, Athens 2006
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X-ray emission and star-formation
Grimm et al. 2003

X-ray binary luminosity function (i.e. number of
sources with luminosity LX) for galaxies with
SFRs in the range0.1-50M?yr-1.

X-ray binary luminosity function scaled by the
SFR of the galaxy. The number of binaries in is
proportional to the SFR N(LXgt2?1038)2.9?SFRM?y
r-1
X-ray Astronomy Summer School, Athens 2006
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Summary III

X-ray binaries dominate X-ray emission in spirals
(star-formation indicator)
Hot gas dominates X-ray emission from early-type
galaxies

X-ray Astronomy Summer School, Athens 2006
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Georgakakis et al. 2006a, bGeorgantopoulos et
al. 2005
X-ray selected galaxies and cosmology

Up to now X-ray properties of galaxies in the
local Universe (i.e. 20Mpc7?107ly)
Chandra and XMM the first X-ray selected galaxy
samples outside the local Universe
Chandra XMM-Newton wide-angle shallow surveys
find galaxies at z0.1 (400Mpc the Universe was
10 its present age)
Chandra Deep Fields identify galaxies to z1
(7?103Mpc the Universe was 50 its present age)
Study how the X-ray properties of galaxies change
with time, i.e. evolution to z1

z 0.07
Needles in the Haystack Survey
X-ray Astronomy Summer School, Athens 2006
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X-ray selected galaxies and cosmology

Up to now X-ray properties of galaxies in the
local Universe (i.e. 20Mpc7?107ly)
Chandra and XMM the first X-ray selected galaxy
samples outside the local Universe
Chandra XMM-Newton wide-angle shallow surveys
find galaxies at z0.1 (400Mpc the Universe was
10 its present age)
Chandra Deep Fields identify galaxies to z1
(7?103Mpc the Universe was 50 its present age)
Study how the X-ray properties of galaxies change
with time, i.e. evolution to z1

z 0.298
Hornschemeier et al. 2003
X-ray Astronomy Summer School, Athens 2006
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Ghosh White 2001
Starforming galaxies at X-ray wavelengths

Star-formation evolution studies at X-rays
Least biased by dust (gt2keV)
Unlike estimators at other wavelengths, includes
information from low-mass stars (e.g. LMXRBs)
information on the evolution timescales of HMXRB
LMXRBs

SFR
X-rays
X-ray Astronomy Summer School, Athens 2006
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Galaxy evolution
2dFGRS