a new chapter in radio astrophysics
DESCRIPTION
Gamma Ray Bursts and Their Afterglows. A New Chapter in Radio Astrophysics. Dale A. Frail National Radio Astronomy Observatory. AAS 200 th meeting, Albuquerque, NM June 2002 The New Radio Universe. A Gamma-Ray Burst in Four Easy Pieces. 1. Central engine. 2. Ultra-relativistic - PowerPoint PPT PresentationTRANSCRIPT
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A New Chapter in Radio
Astrophysics
Dale A. FrailNational Radio Astronomy Observatory
Gamma Ray Bursts and Their Afterglows
AAS 200th meeting, Albuquerque, NM June 2002The New Radio Universe
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A Gamma-Ray Burst in Four Easy Pieces
1. Central engine
2. Ultra-relativistic outflow
3. Internal shocks(gamma-ray burst)
4. External shock(afterglow)
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e
N(e)
N(e) ep
+B
~ B e2
cooling
“universal”
2
1/3
Theoretical Spectra
Flux(p-1)/2
p/2
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Observations vs TheoryG
alam
a et
al.
(199
8)
GRB 970508
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Observations vs Theory
Good agreement between theory and observations
GRB 000926
GRB 980329
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Broadband Afterglow Spectrum
Sar
i, pr
iv. c
omm
.Use the afterglow light
curves and spectra to infer:– the total energy of
the outflow– the geometry of the
outflow– the density structure
of the circumburst medium
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Talk Outline
• The Radio Afterglow Sample– detection statistics
• Fireball size and relativistic expansion• Energetics
– beaming angles and broadband modeling– Sedov-Taylor estimates
• Circumburst Environment– density indicators– dark bursts
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The First Five Years: 1997-2001
Radio
X-rayOptical
Venn DiagramR=1
XOR=12
X=14XO=4
O=5
OR=7 XR=4
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Fireball Size and Expansion
• Rapid (~hrs), narrow-band (~GHz) flux variations– diffractive scintillation
(Goodman 1997)– size at 1 month ~1017cm (3
uas)– superluminal expansion
• Rising spectrum 2 at low frequencies (Katz & Piran)– synchrotron self-absorption– size at 1 month ~1017cm
An early confirmation of the fireball model
Flux variations +/- 50%
“quench”
Narrow band <few GHz
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Energy and Beaming Corrections
• Use isotropic gamma-ray energy as a proxy for total energy in outflow
• Need to correct for the geometry of the outflow
• Signature of a jet is an achromatic break in the light curveFrail et al. (2001)
4D2F=
22D2F=
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Jet Signatures: Optical/X-ray
Piran, Science, 08 Feb 2002
GRB 990510
t-0.82
tjet=1.2 d t-2.18
Harrison et al. (1999)
Achromatic breaks- edge of jet is visible- lateral expansion
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Jet Signatures: Give me a break!
radio
opticalX-ray
jett
Flux
Den
sity
time
-1t -2t
-1/3t
• The jet signature in radio is different- rise decay- “Peak flux cascade”
)1.0( F:Radiative
F:iso Wind,
F:jet ISM,
F:iso ISM,
0.08m
1/3m
1/2m
0m
em
m
m
m
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Peak Flux Cascade: GRB 980329
350 GHz: 2.5 mJy 90 GHz: 1.5 mJy
8.46 GHz: 0.35 mJy4.86 GHz: 0.20 mJy1.43 GHz: 0.10 mJy
Other examples:GRB 970508GRB 980703
Yost et al. (2002)
07.00.59mF m
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Jets Breaks and Opening Angles
• Determining the true gamma-ray energy requires measuring achromatic breaks over a wide range of timescales
• The different jet signature in radio bands gives added confidence– X-ray: flares– Optical: host-dominated,
density fluctuations, lensing, refreshed shocks, wide angle jets
Frail et al. (2001)
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Jets Breaks and Opening Angles
• Determining the true gamma-ray energy requires measuring achromatic breaks over a wide range of timescales
• The different jet signature in radio bands gives added confidence– X-ray: flares– Optical: host-dominated,
density fluctuations, lensing, refreshed shocks, wide angle jets
GRB 980703
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• Criticism: Geometry-corrected gamma-ray energy depends on circumburst density
but • Hydrodynamic evolution of the blast-wave
depends strongly on:– total energy in outflow, geometry of outflow,
and density structure of circumburst medium
Energy and Circumburst Density
…broadband afterglow modeling is the key
-36o
4 cm 10n 10
n1
EtE 4/14/1
o
3/4
,isojet
z
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• Frail et al. (2002) have carried out recent modeling of all radio, optical, NIR and X-ray data–
Broadband Modeling: GRB 980703
3o cm 27n
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• Radio AGs rule out extreme densities and yield
• Most GRB AGs can be described by a jet-like outflow in a constant density medium
• In order to conclusively link GRBs and massive stars we must see the wind signature– Radio measurements are
sensitive to both the absolute value of the gas density and its radial dependence
GRB Environments: GRB 000926
AG
Mod
el
Harrison et al. (2001) vs Piro et al (2001)
-3o cm 10n
)rr)( (i.e., -2
GRB 000926
-34o
-3o cm 104n vscm 30n
-34o cm 104n
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Fireball Calorimetry
• Long-lived radio afterglow makes a transition to NR expansion– no geometric
uncertainties – can employ robust Sedov
formulation for dynamics– compare with
equipartition radius and cross check with ISS-derived radius
• Different methods agree
Frail, Waxman & Kulkarni (2000)
3-o
50o
cm 1n
erg 105 E
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The Population of Dark Bursts
Radio
X-rayOptical
R=1
XOR=12
X=14XO=4
O=5
OR=7 Dark BurstsXR=4
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How Do You Make a Dark Burst?
• Intrinsically faint afterglow– low energy, fast decay, etc.
• Dust extinction– Dust and gas along the line-of-sight or
within the circumburst environment• High redshift
– Absorption by Ly-alpha forest for z>5– predictions of up to 50% of all bursts
…Need a sample of well-localized bursts
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X-ray/Radio Dark Bursts
• host galaxies are at modest redshifts (no z>5 candidates)
• X-ray/radio predict bright optical afterglow (not faint)
• significant extinction required (A_v>4-10)
GRB 981226
GRB 990506 z=1.31
Hol
land
et a
l
Taylor et al. (2000)
Hol
land
et a
l
Fra
il e
t al.
(199
9)
GRB 970828 z=0.958
Bloom et al. (2002)
Piro et al. (2002)
GRB 000210 z=0.846
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Emerging Picture
• a gamma-ray burst is the result of a catastrophic release ~10^51 erg of energy
• the resulting outflow expands (highly) relativistically and has a jet-like geometry– there is a distribution of opening (or viewing)
angles
• the explosion occurs in a gas-rich environment– the measured circumburst density is ~10 cm-3– there is some evidence for progenitor mass-loss
• the most likely progenitor of long-duration GRBs are massive stars (aka collapsar)
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Will radio observations be relevant in the SWIFT era?
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• Can “resolve” the outflow via interstellar scintillation• Samples portion of afterglow spectrum which is vital for
constraining the physical parameters of the fireball• Radio afterglow can “see” wide-angle jets • Long-lived radio afterglow can capture NR transition• Not sensitive to dust obscuration (dusty hosts), Lyman
breaks (z>5), time of day, weather, lunar phase
Conclusions
Radio observations of afterglows have an important (and sometimes unique) role to
play