recent progress on gamma-ray bursts and grb cosmology zigao dai department of astronomy, nanjing...
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Recent Progress on Gamma-Ray Bursts and GRB Cosmology
Zigao Dai
Department of Astronomy, Nanjing University
Sino-French workshop, Beijing, 08/30/2006
Collaborators
• Lu Tan, Huang Yongfeng, Wang Xiangyu, Wei Daming, Cheng Kwongsheng
• Li Zhuo, Wu Xuefeng, Fan Yizhong, Zou Yuanchuan, Shao Lang, Xu Dong, Xu Lei, …
• Zhang Bing, Liang Enwei, Peter Meszaros
Spectral features: broken power laws
with Ep of a few tens to hundreds of keV Temporal features: diverse and
spiky light curves.
Gamma-Ray Bursts
Bimodal distribution in durations
short
long2 s
Outline
I. Pre-Swift progressII. Recent progress and
implicationsIII. GRB cosmology
Most important discoveries in the pre-Swift era
1967: Klebesadel et al.’s discovery 1992: spatial distribution (BATSE) 1997: observations on
multiwavelength afterglows of GRB970228 and detection of the redshift of GRB970508 (BeppoSAX)
1998: association of GRB980425 with SN1998bw(BeppoSAX)
2003: association of GRB030329 with SN2003dh(HETE-2)
Some important discoveries in the pre-Swift era
1993: sub-classes (Kouveliotou et al.) 1994: MeV-GeV emission from GRB 940217
(Hurley et al.) ; 200 MeV emission from GRB 941017 (Gonzalez et al. 2003)
1997: detection of the iron lines in the X-ray afterglow of GRB 970508 (Piro et al.)
1999: optical flash and broken ligh curve of the R-band afterglow of GRB 990123 (Akerlof et al.; Fruchter et al.; Kulkarni et al.)
2002: X-ray flashes (Heise et al.; Kippen et al.) 2005: X-ray flares of GRBs (Piro et al.)
Theoretical progress in the pre-Swift era
1975: Usov & Chibison proposed GRBs at cosmological distances; Ruderman discussed an optical depth >> 1 problem
1986: Paczynski & Goodman proposed the fireball model of cosmological GRBs
1989: Eichler et al. proposed the NS-NS merger model 1990: Shemi & Piran proposed the relativistic fireball model
to solve the optical depth problem 1992: Rees & Meszaros proposed the external shock model of
GRBs; Usov and Duncan & Thompson proposed the magnetar model
1993: Woosley proposed the collapsar model 1994: Paczynski & Xu and Rees & Meszaros proposed the
internal shock model of GRBs; Katz predicted afterglows from GRBs
1995: Sari & Piran analyzed the dynamics of forward-reverse shocks ; Waxman 和 Vietri discussed high-E cosmic rays from GRBs
1997: Waxman & Bahcall discussed high-E neutrinos from GRBs
1997: Meszaros & Rees predicted light curves of afterglows
1998: Sari,Piran & Narayan established standard afterglow model; Vietri & Stella proposed the supranova model; Paczynski proposed the hypernova model; Dai & Lu and Rees & Meszaros proposed energy injection models; Dai & Lu and Meszaros et al. proposed the wind model; Wei & Lu discussed the IC scattering in afterglows ;
1999: Rhoads and Sari et al. proposed the jet model; Sari & Piran explained the optical flash from GRB 990123; Dai & Lu proposed dense environments —— GMC ; Huang et al. established the generic dynamic model; MacFadyen et al. numerically simulated the collapsar model; Derishev et al. proposed the neutron effect in afterglows
2000: some correlations were found, e.g., Fenimore et al. and Norris et al. ; Kumar & Panaitescu proposed the curvature effect in afterglows
2001: Frail et al. found a cluster of the jet-collimated energies; Panaitescu & Kumar fitted the afterglow data and obtained the model parameters
2002: the Amati correlation was found; Zhang & Meszaros analyzed spectral break models of GRBs; Rossi et al. and Zhang & Meszaros discussed the structured jet models; Fan et al. found the magnetized reverse shock in GRB 990123
2003: Schaefer discussed the cosmological use of GRBs;
2004: the Ghirlanda correlation was found; Dai et al. used this relation to constrain the cosmological parameters
Central engine models
NS-NS merger model (Paczynski 1986; Eichler et al. 1989)
Collapsar models (Woosley 1993; Paczynski 1998; MacFadyen & Woosley 1999)
Magnetar model (Usov 1992; Duncan & Thompson 1992)
NS-SS phase transition models (Cheng & Dai 1996; Dai & Lu 1998a; Paczynski & Haensel 2005)
Supranova models (Vietri & Stella 1998)
Collapsar modelNS-NS merger model
Summary: fireball + shock model
Basic assumptions in the standard afterglow model
① A spherical, ultrarelativistic fireball is ejected;
② The total energy of the shocks is released impulsively before their formation;
③ The unshocked medium is homogeneous, and its density is of the order of 1 cm-3;
④ The electron and magnetic energy-density fractions of the shocked medium and the index p of the electron power-law distribution are constant;
⑤ The emission mechanism is synchrotron radiation.
① Jets (Rhoads 1997, 1999; Sari, Piran & Halpern 1999;
Dai & Cheng 2001)
② Postburst energy injection (Dai & Lu 1998a, 2000, 2001; Rees & Meszaros 1998; Panaitescu & Meszaros 1998; Kumar & Piran 2000a,b; Zhang & Meszaros 2001a,b; Nakar & Piran 2003; Dai 2004)
③ Environments including stellar winds and dense media (Dai & Lu 1998b, 1999, 2002; Meszaros, Rees & Wijers 1998; Chevalier & Li 1999, 2000; Dai & Wu 2003; Chevalier et al. 2004)
④ Model parameters changed (Yost et al. 2003)
⑤ Other emission mechanisms including IC scattering (Wei & Lu 1998; Sari & Esin 2001; Panaitescu & Kumar 2001; Zhang & Meszaros 2002)
Physical effects in afterglows
Expectations to Swift
GRB progenitors? Early afterglows? Short-GRB afterglows? Environments? Classes of GRBs? (High-z) GRBs as
astrophysical tools?
Blast wave interaction?
Gehrels et al. 2004, ApJ, 611, 1005
Gehrels et al. 2004; Launch on 20 November 2004
ν ~(5-18)x1014 Hz
Discoveries in the Swift era
1. Prompt optical-IR emission and very early optical afterglows
2. Early steep decay and shallow decay of X-ray afterglows
3. X-ray flares from long/short bursts4. One high-redshift (z=6.295) burst5. Afterglows and host galaxies of short bursts6. Nearby GRB060218 / SN2006aj; nearby
GRB060614 (z=0.125) / no supernova
1. Prompt optical-IR emission and very early optical afterglows
Vestrand et al. 2005, Nature, 435, 178Blake et al. 2005, Nature, 435, 181
Further evidence: Vestrand et al. 2006, Nature, in press
2. Early steep decay and shallow decay of X-ray afterglows
Cusumano et al. 2005, astro-ph/0509689
t -5.5ν-1.60.22
GRB 050319
t -0.54ν-0.690.06
t -1.14ν-0.800.08
Tagliaferri et al. 2005, Nature, 436, 985 (also see Chincarini et al. 2005)
Initial steep decay: tail emission from relativistic shocked ejecta, e.g. curvature effect (Kumar & Panaitescu 2000; Zhang et al. 2006)
Flattening: continuous energy injection (Dai & Lu 1998a,b; Dai 2004; Zhang & Meszaros 2001; Zhang et al. 2006; Nousek et al. 2006), implying long-lasting central engine
Final steepening: forward shock emission
3. X-ray flares from long bursts
Burrows et al. 2005, Science, 309, 1833
Explanation: late internal shocks (Fan & Wei 2005; Zhang et al. 2006; Wu, Dai et al. 2005), implying long-lasting central engine.
Halpern et al. (2006): optical flares
Energy source models of X-ray/optical flares
• Fragmentation of a stellar core (King et al. 2005)
• Fragmentation of an accretion disk (Perna Armitage & Zhang 2005)
• Magnetic-driven barrier in an accretion disk (Proga & Zhang 2006)
• Newborn millisecond pulsar (for short GRB) (Dai, Wang, Wu & Zhang 2006)
4. High-z GRB 050904: z=6.295
Tagliaferri et al. 2005, astro-ph/0509766
Kawai et al. 2006, Nature, 440, 184
X-ray flares of GRB 050904
Watson et al. 2005, Cusumano et al. 2006, Nature, 440, 164
Zou, Dai & Xu 2006, ApJ, in press
5. Afterglow from short GRB050509B
Gehrels et al. 2005, Nature, 437, 851
X-ray afterglow
Another case - GRB050709
Fox et al. 2005, Nature, 437, 845
X-ray:t-1.3
B-band t-1.25
t-2.8
radio
X-ray flare from GRB050709
Villasenor et al. 2005, Nature, 437, 855
光学余辉 : t-1.25
t-2.8
射电余辉 : 上限
X-ray flare at t=100 s
GRB050724: Barthelmy et al. 2005, Nature, 438, 994
Properties of short GRBs
Fox, et al. 2005, Nature, 437, 845
Ages of the host galaxies
Gorosabel et al. 2005, astro-ph/0510141
Summary: Basic features of short GRBs
1. low-redshifts (e.g., GRB050724, z=0.258; GRB050813, z=0.722)
2. Eiso ~ 1048 – 1050 ergs ;3. The host galaxies are old and short
GRBs are usually in their outskirts; support the NS-NS merger model !4. X-ray flares challenge this model!
Rosswog et al., astro-ph/0306418
Ozel 2006, Nature, in press
Support stiff equations of state
Morrison et al. 2004, ApJ, 610, 941
Dai et al. 2006, Science, 311, 1127: differentially-rotating millisecond pulsars, similar to the popular solar flare model.
Roming et al., astro-ph/0605005, Swift BAT (left), KONUS-Wind (right)
Further evidence: GRB060313 prompt flares + late flattening
GRB060313: Roming et al., astro-ph/0605005, Yu Yu’s fitting by the pulsar energy injection model: B~1014 Gauss, P0~1 ms
Further evidence: GRB060313 prompt flares + late flattening
6. Nearby GRB 060218/SN2006aj(Campana et al. 17/39, 2006, Nature, in press)
Nearby GRB, z=0.0335 SN 2006aj association Low luminosity ~1047 ergs/s,
low energy ~1049 ergs Long duration (~900 s in
gamma-rays, ~2600 s in X-rays)
A thermal component identified in early X-rays and late UV/optical band
see J.S. Deng’s talk
GRB 060218: prompt emission(Dai, Zhang & Liang 2006)
Very faint prompt UVOT emission can not be synchrotron emission.
The thermal X-ray component provides a seed photon source for IC.
Steep decay following both gamma-rays and X-rays implies the curvature effect.
Non-thermal spectrum must be produced above the photosphere.
GRB 060218: prompt emission(Dai, Zhang & Liang 2006)
Outline
I. Pre-Swift progressII. Recent progress and
implicationsIII. GRB cosmology
Einstein equations with
Friedmann equations
These equations imply that (1) the expansion of the universe at the present time is accelerating and (2) the universe had once been decelerating.
Krauss, L. M. 1999, Scientific American
deceleration acceleration
Type-Ia SupernovaeType-Ia Supernovae When the mass of an accreting white dwarf increases to the Chandrasekhar limit, this star explodes as an SN Ia.
Hamuy et al. (1993, 1995)
Luminosity distance of a standard candle
DL(z) = [Lp/(4F)]1/2
Supernova CosmologySupernova Cosmology
More standardized candles from low-z SNe Ia:
1) A tight correlation: Lp ~ Δm15 (Phillips 1993)
2) Multi-color light curve shape (Riess et al. 1995)
3) The stretch method (Perlmutter et al. 1999)
4) The Bayesian adapted template match (BATM) method (Tonry et al. 2003)
5) A tight correlation: Lp ~ ΔC12 (B-V colors after the B maximum, Wang X.F. et al. 2005)
see X.F. Wang’s talk Phillips (1993)
Integral Method for Theoretical DL
Calculate 2 (H0,ΩM,Ω) or 2 (H0,ΩM, w), which is model-dependent, and obtain confidence contours from 1σ to 3σ.
or
Accelerating UniverseRiess et al. (1998): 50 SNe Ia
Dotted: excluding SN1997ck (z=0.97)
Accelerating UniversePerlmutter et al. (1999): 42 high-z SNe Ia
Riess et al. (2004, ApJ, 607, 665): 16 SNe Ia discovered by HSTHST.
Transition from deceleration to acceleration: zT = -q0/(dq/dz) = 0.46
The deceleration factor: q(z) = q0 + z(dq/dz)
Riess et al. (2004): Ω= 0.71, q0 < 0 (3σ), and w = -1.02+0.13
-0.19 (1σ), implying that Λis a candidate of dark energy.
Daly et al. 2004, ApJ, 612, 652
Pseudo-SNAP SNIa sample
y(z)=H0dL/(1+z)Differential Method, which is model-independent
Disadvantages in SN cosmology:
1. Dust extinction
2. ZMAX ~ 1.7
zT~0.5
GRBs are believed to be detectable out to very high redshifts up to z~25 (the first stars: Lamb & Reichart 2000; Ciardi & Loeb 2000; Bromm & Loeb 2002). SNe Ia are detected only at redshifts of z 1.7.
SN
High-z GRB 050904: z=6.3
Tagliaferri et al. 2005, astro-ph/0509766
GRB CosmologyGRB Cosmology Advantages over SNe Ia
① GRBs can occur at higher redshifts up to z~25;
② Gamma rays suffer from no dust extinction.
So, GRBs are an attractive probe of the universe.
The afterglow jet model (Rhoads 1999; Sari et al. 1999; Dai & Cheng 2001 for 1<p<2):
Ghirlanda et al. (2004a); Dai, Liang & Xu (2004): a tight correlation with a slope of ~1.5 and a small scatter of 2~0.53, suggesting a promising and interesting probe of cosmography.
M=0.27, =0.73
Physical Explanations Synchrotron radiation + beaming correction (Dai, Liang & Xu
2004; Dai & Lu 2002; Zhang & Meszaros 2002) Annular jet + viewing angle effect (Levinson & Eichler 2005) Comptonization of the thermal radiation flux that is advected
from the base of an outflow (Rees & Meszaros 2005; Thompson, Meszaros & Rees 2006)
Propagation of relativistic jets in the envelopes of massive stars an energy limit (compared to the Chandrasekhar limit)
Two Methods of the Cosmological Use
(Ejet/1050 ergs) = C[(1+z)Ep/100 keV]a
Dai et al. (2004) consider a cosmology-independent correlation, in which C and a are intrinsic physical parameters and may be determined by low-z bursts as in the SN cosmology. Our correlation is a rigid ruler.
Consider a cosmology-dependent correlation (Ghirlanda et al.
2004b; Friedman & Bloom 2005; Firmani et al. 2005). Because C and a are always given by best fitting for each cosmology, this correlation is an elastic ruler, which is dependent of (ΩM, Ω).
The Hubble diagram of GRBs is consistent with that of SNe Ia.
Dai, Liang & Xu (2004) assumed a cosmology-independent correlation.
““GRB Cosmology”GRB Cosmology”
Conclusions
ΩM = 0.35 0.15 (1σ)
w = -0.84+0.57-0.83 (1σ)
Many further studies: Ghirlanda et al. (2004b), Friedman & Bloom (2004), Xu, Dai & Liang (2005), Firmani et al. (2005, 2006), Mortsell & Sollerman (2005), Di Girolamo et al (2005), Liang & Zhang (2005, 2006),
…… A larger sample established by Swift
would be expected to provide further constraints (Swift was launched
on 20 Nov 2004)?
Swift
Cosmology-dependent correlation Cosmology-independent correlation
Xu D., Dai Z.G. & Liang E.W. (2005, ApJ, 633, 603): method 2 cosmology-dependent correlation
Shortcomings of the Ghirlanda relation
• The collimation-corrected gamma-ray energy is dependent on the environmental number density and the gamma-ray efficiency.
• Thus, the Ghirlanda relation is jet model-dependent.
Liang & Zhang 2005, ApJ, 633, 611
Wang & Dai 2006, MNRAS, 368, 371: w=-1 (left); w=w0 (right)
Wang & Dai 2006, MNRAS, 368, 371: w=w0+w1z (left); w=w0+w1z/(1+z) (right)
Schaefer 2006
ww==ww00++ww’’zz
Other works Calibration of GRB luminosity indicators (Liang & Zhang
2006, MNRAS)
Very recently, a new correlation: Liso, Epk and T0.45 , and its
cosmological use (Firmani et al. 2006a, b, c)
Importance: Hopefully, GRBs will provide further constraints on cosmological parameters, complementary to the constraints from CMB and SN —— GRB cosmology.
Xu, Dai & Liang (2005): red contours based on a simulated 157-GRB sample
Perlmutter (2003): smallest contours from SNAP
CMB
Clusters
Explosions SNe Ia GRBsAstrophysical energy sources
Thermonuclear explosion of accreting white dwarfs
Core collapse of massive stars
Standardized candles
Colgate (1979): Lp constant
Frail et al. (2001): E jet constant
More standardized candles
Phillips (1993): Lp~Δm15 (9 low-z SNe Ia)
Ghirlanda et al. (2004a): E jet~Ep (14 high-z bursts)
Other correlations Riess et al. (1995); Perlmutter et al. (1999) …
Liang & Zhang (2005); Firmani et al. (2006)
Recent or future observations
16 HST-detected SNe Ia up to z~1.7 (Riess et al. 2004)
A large SVOMSVOM-detected sample up to higher z
Comments on research status
From infancy to childhood (1998) to adulthood (SNAP)
At babyhood (to childhood by future missions?)
Comparison of Cosmological Probes
Summary: GRB cosmology Finding: GRBs appear to provide an independent,
promising probe of the early universe (high-z SFR and IGM) and dark energy—one of the most enigmatic clouds.
Status: The current GRB cosmology is at babyhood because of the small sample and model assumptions.
Prospect: In the future, the GRB cosmology would progress from its infancy to childhood, if a large sample of some subclasssome subclass (including low- & high-z bursts) and a more standardized candle are found.
Experience: “Chance favors (only) the prepared mind” (said Trimble V. 2003 on the GRB meeting in Santa Fe).
Proposal: Lamb et al. 2005 proposed a satellite project for GRB cosmology (gamma- & X-ray and optical detectors), and the Sino-French GRB mission ……
Requirements to future missions from GRB cosmology
• Based on – Ghirlanda relation
– Liang & Zhang luminosity indicator
– Firmani et al. relation
• Science:– Constraints on cosmological parameters
– properties of dark energy
– Systematics different from SNe
• Requirements (broadband observations):– Full set of spectral parameters: α, β, Epeak
– Jet break time (optical, X-ray)
– Redshift
– A large sample of GRBs…
Thank you !Thank you !