GRB physics and cosmology with spectrum-energy correlation
Lorenzo Amati
INAF – IASF Bologna (Italy)
Outline
GRB: standard scenarios and open issues
Spectrum-energy correlation and its implications
GRB cosmology with spectrum-energy correlation
Future perspectives
LONG
energy budget up to >1054 erg long duration GRBs metal rich (Fe, Ni, Co) circum-burst environment GRBs occur in star forming regions GRBs are associated with SNe likelycollimated emission
energy budget up to 1051 - 1052 erg short duration (< 5 s) clean circum-burst environment old stellar population
SHORT
Standard scenarios for GRB origin
ms time variability + huge energy + detection of GeV photons -> plasma occurring ultra-relativistic ( > 100) expansion (fireball or firejet) non thermal spectra -> shocks synchrotron emission (SSM) fireball internal shocks -> prompt emission fireball external shock with ISM -> afterglow emission
Standard scenarios for GRB phisics
most time averaged spectra of GRBs are well fit by synchrotron shock models at early times, some spectra inconsistent with optically thin synchrotron: possible contribution of IC component and/or thermal emission from the fireball photosphere
GRB prompt emission physics
Open issues (several, despite obs. progress)
Afterglow emission physics
consistency with synchrotron predictions found e.g. for GRB 970508
deviations in the X-ray band from synchrotron: found for GRB000926 (Harrison et al. 2001) and GRB010222 (in ‘t Zand et al. 2001).
they are consistent with relevant Inverse Compton on the low energy photons
~ -3
~ -0.7
~ - 1.3
~ -210^2 – 10^3 s10^4 – 10^5 s
10^5 – 10^6 s
( 1 min ≤ t ≤ hours )
Early afterglow
new features seen by Swift in X-ray early afterglow light curves (initial very steep decay, early breaks, flares) mostly unpredicted and unexplained
initial steep decay: continuation of prompt emission, mini break due to patchy shell, IC up-scatter of the reverse shock sinchrotron emission ?
flat decay: probably “refreshed shocks” (due either to long duration ejection or short ejection but with wide range of ) ? flares: could be due to: refreshed shocks, IC from reverse shock, external density bumps, continued central engine activity, late
internal shocks…
CGRO/EGRET detected VHE (from 30 MeV up to 18 GeV) photons for a few GRBs
VHE emission can last up to thousends of s after GRB onset
average spectrum of 4 events well described by a simple power-law with index ~2 , consistent with extension of low energy spectra
GRB 941017,measured by EGRET-TASC shows a high energy component inconsistent with synchrotron shock model
Recent AGILE detection of 2-3 >500 MeV photons
GeV emission
GRB990123: first detection (by ROTSE) of prompt optical emission
optical light curve does not follow high energy light curve: evidence for a different origin (reverse shock ?)
GRB041219 (RAPTOR) contrary to GRB990123, the optical light curve follows the high energy light curve: evidence for same origin (internal shocks ?)r
Prompt optical emission
the challenging “naked eye” GRB080319B: complexity and energetics
Bloom et al. 2008
evidence of overdense and metal enriched circum-burst environment from absorption and emission features
emission lines in afterglow spectrum detected by BeppoSAX but not by Swift
Swift detects intrinsic NH for many GRB afterglows
optical (Ly) NH often inconsistent with X-ray NH
Circum-burst environment
prompt
afterglow
Amati et al.,Science, 2000 Antonelli et al., ApJ, 2001
Collimated or isotropic ?
lack of jet breaks in several Swift X-ray afterglow light curves, in some cases, evidence of achromatic break
challenging evidences for Jet interpretation of break in afterglow light curves or due to present inadequate sampling of optical light curves w/r to X-ray ones and to lack of satisfactory modeling of jets ?
GRB/SN connection
are all long GRB produced by a type Ibc SN progenitor ?
which fraction of type Ibc SN produces a GRB, and what are their peculiarities ?
are the properties (e.g., energetics) of the GRB linked to those of the SN ?
In the spectral lag – peak luminosity plane, GRB060614 lies in the short GRBs region -> need for a new GRB classification scheme ?
Gehrels et al., Nature, 2006
short / long classification and physics Swift GRB 060614: a long GRB with a very high lower limit to the magnitude of
an associated SN -> association with a GRB/SN is excluded high lower limit to SN also for GRB 060505 (and, less stringently, XRF 040701)
EMBH / fireshell model (Ruffini et al.)
CannonBall (CB) (Dar et al.)
Precessing jet (Fargion’s talk), stochastic wakefield plasma acceleration (Barbiellini et al.), ns-quark star transition, …
Short GRB as SGR giant outburst at high z
Alternative scenarios
GRB spectra typically described by the empirical Band function with parameters = low-energy index, = high-energy index, E0=break energy
Ep = E0 x (2 + a) = observed peak energy of the F spectrum
The Ep,i – Eiso correlation
from redshift, fluence and spectrum, it is possible to estimate the cosmologica-rest frame peak energy, Ep,i, and the radiated energy assuming isotropic emission, Eiso
isotropic luminosities and radiated energy are huge; both Ep,i and Eiso and span several orders of magnitude
(Amati, MNRAS, 2006)(Amati, MNRAS, 2006)
Ep,i = Ep x (1 + z)
log(Ep,i )= 2.52 , = 0.43log(Eiso)= 1.0 , = 0.9
Amati et al. (2002) analyzed a sample of 12 BeppoSAX events with known redshift
we found evidence of a strong correlation between Ep,i and Eiso , highly significant ( = 0.949, chance prob. 0.005%) despite the low number of GRBs included in the sample
Ep,i = kEiso
(0.52+/-0.06)
Amati et al. , A&A, 2002
analysis of an updated sample of long GRBs/XRFs with firm estimates of z and Ep,i (41 events) gives a chance probability for the Ep,i-Eiso correlation of ~10-15 and a slope of 0.57+/-0.02
the scatter of the data around the best fit power-law can be fitted with a Gaussian with (logEp,i) ~ 0.2 (~0.15 extra-poissonian)
confirmed by the most recent analysis (more than 70 events, Ghirlanda et al. 2008, Amati et al. 2008)
only firm outlier the local peculiar GRB 980425 (GRB 031203 debated)
Amati et al. 2008
all long Swift GRBs with known z and published estimates or limits to Ep,i are consistent with the correlation the parameters (index, normalization,dispersion) obatined with Swift GRBs only are fully consistent with what found before Swift allows reduction of selection effects in the sample of GRB with known z -> the Ep,i-Eiso correlation is
passing the more reliable test: observations !
Amati 2006, Amati et al. 2008
physics of prompt emission still not settled, various scenarios: SSM internal shocks, IC-dominated internal shocks, external shocks, photospheric emission dominated models, kinetic energy dominated fireball , poynting flux dominated fireball)
e.g., Ep,i -2 L1/2 t-1 for syncrotron emission from a power-law distribution of electrons generated in an internal shock (Zhang & Meszaros 2002, Ryde 2005)
e.g., Ep,i Tpk 2 L-1/4 in scenarios in whch for comptonized thermal emission from the photosphere dominates (e.g. Rees & Meszaros 2005, Thomson et al. 2006)
Implications of the Ep,i – Eiso correlation
jet geometry and structure
XRF-GRB unification models
viewing angle effects
Uniform/variable jet PL-structured /universal jet
Uniform/variable jet PL-structured /universal jet
GRB980425 not only prototype event of GRB/SN connection but closest GRB (z = 0.0085) and sub-energetic event (Eiso ~ 1048 erg, Ek,aft ~ 1050 erg)
GRB031203: the most similar case to GRB980425/SN1998bw: very close (z = 0.105), SN2003lw, sub-energetic
The Ep,i – Eiso correlation and sub-energetic GRB
the most common explanations for the (apparent ?) sub-energetic nature of GRB980425 and GRB031203 and their violation of the Ep,i – Eiso correlation assume that they are NORMAL events seen very off-axis (e.g. Yamazaki et al. 2003, Ramirez-Ruiz et al. 2005) =[(1 - cos(v - ))]-1 , Ep Eiso )
=1÷2.3 -> Eiso ÷ )
Yamazaki et al., ApJ, 2003 Ramirez-Ruiz et al., ApJ, 2004
but, contrary to GRB980425 and (possibly) GRB031203, GRB060218 is consistent with the Ep,i-Eiso correlation -> evidence that it is a truly sub-energetic GRB -> likely existence of a population of under-luminous GRB detectable in the local universe
also XRF 020903 is very weak and soft (sub-energetic GRB prompt emission) and is consistent with the Ep-Eiso correlation
Amati et al., 2007
GRB 060218, a very close (z = 0.033, second only to GRB9809425), with a prominent association with SN2006aj, and very low Eiso (6 x 1049 erg) and Ek,aft -> very similar to GRB980425 and GRB031203
GRB060218 was a very long event (~3000 s) and without XRT mesurement (0.3-10 keV) Ep,i would have been over-estimated and found to be inconsistent with the Ep,i-Eiso correlation
Ghisellini et al. (2006) found that a spectral evolution model based on GRB060218 can be applied to GRB980425 and GRB031203, showing that these two events may be also consistent with the Ep,i-Eiso correlation
sub-energetic GRB consistent with the correlation; apparent outliers(s) GRB 980425 (GRB 031203) could be due to viewing angle or instrumental effect
Recent Swift detection of an X-ray transient associated with SN 2008D at z = 0.0064, showing a light curve and duration similar to GRB 060218
Peak energy limits and energetics consistent with a very-low energy extension of the Ep,i-Eiso correlation Evidence that this transient may be a very soft and weak GRB (XRF 080109), thus confirming the existence of a population of
sub-energetic GRB ?
Modjaz et al., ApJ, 2008 Li, MNRAS, 2008
only very recently, redshift estimates for short GRBs
all SHORT Swift GRBs with known redshift and lower limits to Ep.i are inconsistent with the Ep,i-Eiso correlation intriguingly, the soft tail of GRB050724 is consistent with the correlation GRB 060614: no SN, first pulse inconsistent with correlation, sfto/long tail consistent: evidence that two different emission mechanisms are at work in both short and long GRB, with different relative efficiency in the two classes (thus generating also intermediate)
Ep,i – Eiso correlation and short GRBs
Amati, NCimB, 2006
GRB-SN connection and the Ep,i-Eiso correlation
GRB 060218 and other GRB with firmest evidence of association with a SN are consistent with the Ep,i-Eiso correlation
GRB 060614: the long GRB with a very deep lower limit to the magnitude of an associated SN is consistent with the correlation too
GRB 060505: stringent lower limit to SN magnitude, inconsistent with correlation, but it is likely short
XRF 08019 / SN 2008D: possible very low energy GRB, possibly consistent with with the correlation
Further evidence that GRB properties are independent on those of the SN
Amati et al. A&A, 2007
GRB have huge luminosity, a redshift distribution extending far beyond SN Ia
high energy emission -> no extinction problems
unfortunately, they are not standard candles !
but need to investigate their properties to find ways to standardize them (if possible)
GRB cosmology with Ep,i – Eiso correlation
the Ep,i-Eiso correlation becomes tighter when adding a third observable: jet opening angle (jet -> E = [1-cos(jet)]*Eiso (Ghirlanda et al. 2004) or “high signal time” T0.45 (Firmani et al. 2006)
the logarithmic dispersion of these correlations is very low: can they be used to standardize GRB ?
jet angle inferred from break time in optical afterglow decay, while Ep,i-Eiso-T0.45 correlation based on prompt emission properties only
Standardizing GRB with 3-parameters spectrum-energy correlations
general purpouse: estimate c.l. contours in 2-param surface (e.g. M-)
general method: construct a chi-square statistics for a given correlation as a function of a couple cosmological parameters
method 1 – luminosity distance: fit the correlation and construct an Hubble diagram for each couple of cosmological parameters -> derive c.l. contours based on chi-square
Methods (e.g., Ghirlanda et al, Firmani et al., Dai et al., Zhang et al.):
Ep,i = Ep,obs x (1 + z)
Dl = Dl (z, H0, M, , …)
Ghirlanda et al., 2004
method 2 – minimum correlation scatter: for each couple of cosm.parameters compute Ep,i and Eiso (or E), fit the points with a pl and compute the chi-square -> derive c.l. contours based on chi-square surface
method 3: bayesian method assuming that the correlation exists and is unique
Firmani et al. 2007
Ghirlanda, Ghisellini et al. 2005, 2006,2007
What can be obtained with 150 GRB with known z and Ep and complementarity with other probes (SN Ia, CMB)
complementary to SN Ia: extension to much higher z even when considering the future sample of SNAP (z < 1.7), cross check of results with different probes
physics of prompt emission still not settled, various scenarios: SSM internal shocks, IC-dominated internal shocks, external shocks, photospheric emission dominated models, kinetic energy dominated fireball , poynting flux dominated fireball)
e.g., Ep,i -2 L1/2 t-1 for syncrotron emission from a power-law distribution of electrons generated in an internal shock (Zhang & Meszaros 2002, Ryde 2005); for Comptonized thermal emission
geometry of the jet (if assuming collimated emission) and viewing angle effects also may play a relevant role
Drawbacks: lack of solid physical explanation
Drawbacks: lack of calibration
differently to SN Ia, there are no low-redshift GRB (only 1 at z < 0.1) -> correlations cannot be calibrated in a “cosmology independent” way
would need calibration with a good number of events at z < 0.01 or within a small range of redshift -> neeed to substantial increase the number of GRB with estimates of redshift and Ep
Bayesian methods have been proposed to “cure” the circularity problem (e.g., Firmani et al., 2006), resulting in slightly reduced contours w/r to simple (and circularity free) scatter method (using Lp,iso-Ep,i-T0.45 corr.)
“Crisis” of 3-parameters spectrum-energy correlations
Recent debate on Swift outliers to the Ep-E correlation (including both GRB with no break and a few GRB with chromatic break)
Recent evidence that the dispersion of the Lp-Ep-T0.45 correlation is significantly higher than thought before and comparable to the Ep,i-Eiso corr.
Campana et al. 2007 Rossi et al. 2008
Using the simple Ep,i-Eiso correlation for cosmology
Based on only 2 observables:
a) much higher number of GRB that can be used
b) reduction of systematics
Evidence that a fraction of the extrinsic scatter of the Ep,i-Eiso correlation is due to choice of cosmological parameters used to compute Eiso
Amati et al. 2008
Simple PL fit70 GRB
By quantifying the extrinsic scatter with a proper log-likelihood method, M can be constrained to 0.04-0.40 (68%) for a flat CDM universe (M = 1 excluded at 99.9% c.l.)
releasing assumption of flat universe still provides evidence of low M, with a low sensitivity to
significant constraints on both M and (and likely on dark energy EOS) expected from sample enrichment and z extension by present and next GRB experiments (e.g., Swift, Konus_WIND, GLAST, SVOM)
completely independent on other cosmological probes (e.g., CMB, type Ia SN, BAO; clusters…) and free of circularity problems
Amati et al. 2008
70 REAL
70 REAL + 150 SIM.
The future: what is needed ? increase the number of z estimates, reduce selection effects and optimize coverage of the fluence-Ep plane in the sample of GRBs with known redshift
more accurate estimates of Ep,i by means of sensitive spectroscopy of GRB prompt emission from a few keV (or even below) and up to at least ~1 MeV
Swift is doing greatly the first job but cannot provide a high number of firm Ep estimates, due to BAT ‘narrow’ energy band (sensitive spectral analysis only from 15 up to ~200 keV)
Ep estimates for some Swift GRBs from Konus (from 15 keV to several MeV) ant, to minor extent, RHESSI and SUZAKU
NARROW BAND
BROAD BAND
2008(-2011 ?): GLAST (AGILE) + Swift:
accurate Ep (GLAST/GBM = 15-5000 keV) and z estimate (plus study of GeV emission) for simultaneously detected events
by assuming that Swift will follow-up ALL GLAST GRB, about 80 GRB with Ep and z in 3 years
AGILE and GLAST: second peak at E > 100 MeV ? (e.g., IC like in Blazars)
In the 2011-2015 time frame a significant step forward expected from SVOM:
spectral study of prompt emission in 1-5000 keV -> accurate estimates of Ep and reduction of systematics (through optimal continuum shape determination and measurement of the spectral evolution down to X-rays)
fast and accurate localization of optical counterpart and prompt dissemination to optical telescopes -> increase in number of z estimates and reduction of selection effects
optimized for detection of XRFs, short GRB, sub-energetic GRB
substantial increase of the number of GRB with known z and Ep -> test of correlations and calibration for their cosmological use
GRB can be used as cosmological beacons for study of the IGM up to z > 6
Because of the association with the death of massive stars GRB allow the study the evolution of massive star formation and the evolution of their host galaxy ISM back to the early epochs of the Universe (z > 6)
GRB as cosmological beacons: EDGE/XENIA (under study)
EDGE Team
End of the talk
Backup slides
Gamma-Ray BurstsGamma-Ray Bursts
most of the flux detected from 10-20 keV up to 1-2 MeV measured rate (by an all-sky experiment on a LEO satellite): ~0.8 / day bimodal duration distribution fluences (= av.flux * duration) typically of ~10-7 – 10-4 erg/cm2
shortlong
• CGRO/EGRET detected VHE (from 30 MeV up to 18 GeV) photons for a few GRBs
• VHE emission can last up to thousends of s after GRB onset
• average spectrum of 4 events well described by a simple power-law with index ~2 , consistent with extension of low energy spectra
The GRB phenomenon: VHE
afterglow emission (> 1997): X, optical, radio counterpartsafterglow emission (> 1997): X, optical, radio counterparts
• host galaxies long GRBs: blue, usually regular and high star forming, GRB located in star forming regions
• host galaxies of short GRBs (very recent): elliptical, irregular galaxies, away from star forming region (but still unclear)
GRB 050509b
ShortLong
… and host galaxies
in 1997 discovery of afterglow emission by BeppoSAXin 1997 discovery of afterglow emission by BeppoSAX
first X, optical, radio counterparts, redshifts, energeticsfirst X, optical, radio counterparts, redshifts, energetics
GRB 970508, Metzger et al., Nature, 1997
GRB 980425, a normal GRB detected and localized by WFC and NFI, but in temporal/spatial coincidence with a type Ic SN at z = 0.008 (chance prob. 0.0001)
further evidences of a GRB/SN connection: bumps in optical afterglow light curves and optical spectra resembling that of GRB980425
1998: GRB/SN connection
• evidence of overdense and metal enriched circum-burst environment from absorption and emission features found in a few cases
circum-burst environment
• BeppoSAX era
prompt
afterglow
>2005 prompt – afterglow • Swift era
The Ep,i-Eiso correlation is the most firm GRB correlation followed by all normal GRB and XRF
Swift results and recent analysis show that it is not an artifact of selection effects
The existence, slope and extrinsic scatter of the correlation allow to test models for GRB prompt emission physics
The study of the locatios of GRB in the Ep,i-Eiso plane help in indentifying and understanding sub-classes of GRB (short, sub-energetic, GRB-SN connection)
Conclusions - IConclusions - I
Given their huge luminosities and redshift distribution extending up to at least 6.3, GRB are potentially a very powerful tool for cosmology and complementary to other probes (CMB, SN Ia, clusters, etc.)
The use of spectrum-energy correlations to this purpouse is promising, but:
need to substantial increase of the # of GRB with known z and Ep (which will be realistically allowed by next GRB experiments: Swift+GLAST/GBM, SVOM,…)
need calibration with a good number of events at z < 0.01 or within a small range of redshift
need solid physical interpretation
identification and understanding of possible sub-classes of GRB not following correlations
Conclusions - IIConclusions - II
Tests and debatesTests and debates
Nakar & Piran and Band & Preece 2005: a substantial fraction (50-90%) of BATSE GRBs without known redshift are potentially inconsistent with the Ep,i-Eiso correlation for any redshift value
they suggest that the correlation is an artifact of selection effects introduced by the steps leading to z estimates: we are measuring the redshift only of those GRBs which follow the correlation
they predicted that Swift will detect several GRBs with Ep,i and Eiso inconsistent with the Ep,i-Eiso correlation
Ghirlanda et al. (2005), Bosnjak et al. (2005), Pizzichini et al. (2005): most BATSE GRB with unknown redshift are consistent with the Ep,i-Eiso correlation
different conclusions mostly due to the accounting or not for the dispersion of the correlation
Debate based on BATSE GRBs without known redshiftDebate based on BATSE GRBs without known redshift
Swift / BAT sensitivity better than BATSE for Ep < ~100 keV, slightly worse than BATSE for Ep > ~100 keV but better than BeppoSAX/GRBM and HETE-2/FREGATE -> more complete coverage of the Ep-Fluence plane
Band, ApJ, (2003, 2006)
CGRO/BATSE
Swift/BAT
Swift GRBs and selection effectsSwift GRBs and selection effects
Ghirlanda et al., MNRAS, (2008)
fast (~1 min) and accurate localization (few fast (~1 min) and accurate localization (few arcesc) of GRBs -> prompt optical follow-up with arcesc) of GRBs -> prompt optical follow-up with large telescopes -> large telescopes -> substantial increase of substantial increase of redshift estimates and reduction of selection redshift estimates and reduction of selection effects in the sample of GRBs with known effects in the sample of GRBs with known redshiftredshift
fast slew -> observation of a part (or most, fast slew -> observation of a part (or most, for very long GRBs) of prompt emission down to for very long GRBs) of prompt emission down to 0.2 keV with unprecedented sensitivity –> 0.2 keV with unprecedented sensitivity –> following complete spectra evolution, detection following complete spectra evolution, detection and modelization of low-energy and modelization of low-energy absorption/emission featuresabsorption/emission features -> better estimate -> better estimate of Ep for soft GRBsof Ep for soft GRBs
drawback: BAT “narrow” energy band allow drawback: BAT “narrow” energy band allow to estimate Ep only for ~15-20% of GRBs (but to estimate Ep only for ~15-20% of GRBs (but for some of them Ep from HETE-2 and/or Konusfor some of them Ep from HETE-2 and/or Konus
GRB060124, Romano et al., A&A, 2006
all long Swift GRBs with known z and published estimates or limits to Ep,i are consistent with the correlationall long Swift GRBs with known z and published estimates or limits to Ep,i are consistent with the correlation the parameters (index, normalization,dispersion) obatined with Swift GRBs only are fully consistent with what found beforethe parameters (index, normalization,dispersion) obatined with Swift GRBs only are fully consistent with what found before Swift allows reduction of selection effects in the sample of GRB with known z -> the Ep,i-Eiso correlation is Swift allows reduction of selection effects in the sample of GRB with known z -> the Ep,i-Eiso correlation is
passing the more reliable test: observationspassing the more reliable test: observations ! !
Amati 2006, Amati et al. 2008
very recent claim by Butler et al.: 50% of Swift very recent claim by Butler et al.: 50% of Swift GRB are inconsistent with the pre-Swift Ep,i-Eiso GRB are inconsistent with the pre-Swift Ep,i-Eiso correlationcorrelation
but Swift/BAT has a narrow energy band: 15-but Swift/BAT has a narrow energy band: 15-150 keV, nealy unesuseful for Ep estimates, 150 keV, nealy unesuseful for Ep estimates, possible only when Ep is in (or close to the possible only when Ep is in (or close to the bounds of ) the passband (15-20%) and with low bounds of ) the passband (15-20%) and with low accuracyaccuracy
comparison of Ep derived by them from BAT comparison of Ep derived by them from BAT spectra using Bayesian method and those spectra using Bayesian method and those MEASURED by Konus/Wind show they are MEASURED by Konus/Wind show they are unreliableunreliable
as shown by the case of GRB 060218, missing as shown by the case of GRB 060218, missing the soft part of GRB emission leads to the soft part of GRB emission leads to overestimate of Epoverestimate of Ep
Full testing and exploitation of spectral-energy correlations may be provided by Full testing and exploitation of spectral-energy correlations may be provided by EDGE in the > 2015 time frameEDGE in the > 2015 time frame
in 3 years of operations, EDGE will detect perform sensitive spectral analysis in 8-2500 keV in 3 years of operations, EDGE will detect perform sensitive spectral analysis in 8-2500 keV for ~150-180 GRBfor ~150-180 GRB
redshift will be provided by optical follow-up and EDGE X-ray absorption spectroscopy (use redshift will be provided by optical follow-up and EDGE X-ray absorption spectroscopy (use of microcalorimeters, GRB afterglow as bkg source)of microcalorimeters, GRB afterglow as bkg source)
substantial improvement in number and accuracy of the estimates of Esubstantial improvement in number and accuracy of the estimates of Epp , which are critical , which are critical for ultimately testing the reliability of spectral-energy correlations and their use for the estimates for ultimately testing the reliability of spectral-energy correlations and their use for the estimates of cosmological parametersof cosmological parameters
extending to high energies (1-2 MeV):extending to high energies (1-2 MeV):
due to the broad spectral curvature of GRBs, a WFM with a limited energy band (<150-200 due to the broad spectral curvature of GRBs, a WFM with a limited energy band (<150-200 keV) will allow the determination of EkeV) will allow the determination of Epp for only a small fraction of events and with low accuracy for only a small fraction of events and with low accuracy (e.g., Swift/BAT ~15%)(e.g., Swift/BAT ~15%)
an extension up to 1-2 MeV with a good average effective area (~600cman extension up to 1-2 MeV with a good average effective area (~600cm22@600 keV) in the @600 keV) in the FOV of the WFM is requiredFOV of the WFM is required
-> baseline solution: WFM + GRB Detector based on crystal scintillator-> baseline solution: WFM + GRB Detector based on crystal scintillator
accuracy of a few % for GRB with 15-150 keV fluence > 10accuracy of a few % for GRB with 15-150 keV fluence > 10-6-6 erg cm erg cm-2-2 over a broad range of over a broad range of EEpp (20-1500) (20-1500)
WFM: 2mm thick CZT detector, eff. Area~500 cm2@100 keV, FOV~1.4sr
WFM + GRBD (5cm thick NaI, 850cm2 geom.area)
Pow.law fit Pow.law fit
extending to low energies (1 keV)extending to low energies (1 keV)
GRB060218 was a very long event (~3000 s) and without XRT mesurement (0.3-10 keV) GRB060218 was a very long event (~3000 s) and without XRT mesurement (0.3-10 keV) Ep,i would have been over-estimated and found to be inconsistent with the Ep,i-Eiso correlationEp,i would have been over-estimated and found to be inconsistent with the Ep,i-Eiso correlation
Ghisellini et al. (2006) found that a spectral evolution model based on GRB060218 can be Ghisellini et al. (2006) found that a spectral evolution model based on GRB060218 can be applied to GRB980425 and GRB031203, showing that these two events may be also consistent applied to GRB980425 and GRB031203, showing that these two events may be also consistent with the Ep,i-Eiso correlationwith the Ep,i-Eiso correlation
missing the X-ray prompt emission -> overestimate of Epmissing the X-ray prompt emission -> overestimate of Ep
In some cases, Ep estimates form different instruments are inconsistent with each other -> particular attention has to be paid to systematics in the estimate of Ep (limited energy band, data truncation effects, detectors sensitivities as a function of energies, etc.)
include X-ray flares (and the whole afterglow emission) in the estimate of Ep,i and Eiso
e.g., 060218, 061007, 070110
Swift has shown how fast accurate localization and follow-up is critical in the reduction of selection effects in the sample of GRB with known z
increasing the number of GRB with known z and accurate estimate of Ep is fundamental for calibration and verification of spectral energy correlations and their use for estimate of cosmological parameters (sim. by G. Ghirlanda)
consider BATSE 25-2000 keV fluences and spectra for 350 bright GRBs
Ep,i = K x Eisom , Ep,i = Ep x (1+z), Eiso=(Sx4DL2)/(1+z)
Ep,i-Eiso correlation re-fitted by computing Eiso from 25*(1+z) to 2000*(1+z) gives K ~100, m ~0.54 , (logEp,i) ~ 0.2, Kmax,2 ~ 250
-> Smin,n = min[(1+z)2.85/(4DL2)] x (Ep/Kmax,n)1.85 (min. for z = 3.8)
Adapted from Kaneko et al., MNRAS, 2006
2
only a small fraction (and with substantial uncertainties in Ep) is below the 2 limit !
Open issues (several, despite recent huge observational advancements)
Prompt and afterglow emission mechanisms: still to be settled
early afterglow (steep decay, flat decay, flares): to be understood
GeV / TeV emission: need for new measurements to test models
X/gamma-ray polarization: need of measurements to test models
short vs. long events: emission mech. and GRB/SN connection
sub-energetic GRB and GRB rate: to be investigated -> SFR evolution
collimated emission: yes or no ?
spectrum-energy correlations and GRB cosmology: explanations and test
… and more !
jet angles derived from the achromatic break time, are of the order of few degrees
the collimation-corrected radiated energy spans the range ~5x1040 – 1052 erg-> more clustered but still not standard
recent observations put in doubt jet interpretation of optical break
confirmation of expectations based on the fact that short GRBs are harder and have a lower fluence
spectra of short GRBs consistent with those of long GRBs in the first 1-2 s
evidences that long GRBs are produced by the superposition of 2 different emissions ?
e.g., in short GRBs only first ~thermal part of the emission and lack or weakness (e.g. due to very high for internal shocks or low density medium for external shock) of long part
long weak soft emission is indeed observed for some short GRBs
Ghirlanda et al. (2004)
no secure detection of polarization of prompt emission (some information from INTEGRAL and BATSE ?)
polarization of a few % for some optical / radio afterglows
radiation from synchrotron and IC is polarized, but a high degree of polarization can be detected only if magnetic field is uniform and perpendicular to line of sight
small degree of polarization detectable if magnetic field is random, emission is collimated (jet) and we are observing only a (particular) portion of the jet or its edge
Polarization