measuring the cosmological parameters with gamma-ray bursts massimo della valle european southern...
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Measuring the cosmological
parameters with Gamma-Ray Bursts
Massimo Della ValleEuropean Southern Observatory (ESO-Munchen)
ICRANet (Pescara)INAF-Osservatorio Astronomico di Capodimonte (Napoli)
Outline
• The measurements of m and with
SNe-Ia
• A short discussion of the Supernova systematics: the need of an independent measurement of m and
• Our measurements of m obtained via Epeak-Eiso (“Amati”) relationship.
Amati, Guidorzi, Frontera, Landi, Finelli and Montanari
Ferrara University
Measuring the cosmological parameters means to study the expansion rate of the Universe, and this is a (relatively) easy task
All it takes is to measure velocities and
distances for a class of cosmological
objects and to plot one vs. the other….
The Hubble Diagram
5log5 DMmin the low red-shift limit(v=HoxD)
MHczm o log525log5
Hubble &
Humason
1931
AKzDMm ML 25)];;(log[5
The Hubble Diagram at high z
For an object of known absolute magnitude M, the measurement of the apparent magnitude m at a given z is sensitive to the universal parameters, through the luminosity distance:
z
MoL dzzzkkSkHczD0
5.0325.05.0 ''11|| ||1
sin(x) if k<0
x if k=0
sinh(x)if k>0
S(x)=
Mk 1
2
Moq
Standard Candles
A population of unevolving sources, having a fixed intrinsic luminosity at
all redshifts
AKzDMm ML 25)];;(log[5
The problem is to find a class of objects as bright as galaxies (to be detected up to cosmological distances) but which does not evolve
Pioneering Hubble diagrams (Sandage et al. 1976) provided formal values of qo=10.5 (cfr. ~ -0.5). These measurements (based on galaxies luminosity) cannot be trusted because of the stellar population evolution and merging.
The evolution destroys the concept of standard candle (which is independent of age)
In the last decade several pieces of observations converged to identify this class of very bright and no-evolving objects with
Supernovae
Supernova Classification
Thermonuclearexplosion ofwhite dwarfs
SNe
Core collapse of massive single stars
II
Ib (strong He)
I
IIl, IIn (Balmer emission)
IIp (P-Cygni), IIb
Ia (strong Si)
H
No H
Ic (weak He)
Core collapse of massive stars (likely) in binary systemsHigh KE=HNe
The commonly accepted idea is that SNe-Ia are the thermonuclear disruption of C-O WDs (3-8M) in binary systems.
Are they standard candles ?
13
SN (Ia) Diversity from Observations
SNe-Ia have been believed, in the past to form an “homogeneous” class of objetcs. Both photometrically (~0.3 mag at max) than spectroscopically (similar SED at the same stages)
Barbon,Ciatti & Rosino 1974
Filippenko 1997
Cappellaro et al. 1997
Cappellaro et al. 1997
bmaM dB 15
Type Ia Supernovae as Standard Candles
After correction for light-curve shape, supernovae become “calibrated” candles with ~0.15 magnitude dispersion.
bmaM dB 15
(1998)
Perlmutter et al. 1997
Perlmutter et al. 1998
Riess at al. 1998
Schmidt et al. 1998
Perlmutter et al. 1999
Riess et al. 2001
Tonry et al. 2003
Knopp et al. 2003
Riess et al. 2004
Astier et al. 2006
……..and more
Perlmutter et al. (1998)
m=0.6±0.2
1999
Perlmutter et al. (1999)
m~ 0.28; ~ 0.72
Riess 2004
m~ 0.29; ~ 0.71
The two teams consistently found that SNIa at redshifts z ~ 0.5 appear dimmer than expected by ~0.25 magnitudes. z ~ 0.5 is the transition epoch between acceleration and deceleration.This suggests (after assuming a flat universe) that the expansion of the Universe is accelerating, propelled by “dark energy”, with
~ 0.71 and M ~ 0.29.
Once we combine SN data with external flat-Universe constraints (WMAP), we find w= -1.02(w <- 0.76 at the 95% confidence level)and w’=0, both implies DE=cosmological constant.
M
Riess et al. 2004
Conclusions from SNe
SN Chinks: Systematics
The cosmological interpretation rely on the lack of evolutionary effects on progenitors of type Ia SNe.
Two populations: 50% prompt + 50% exp
“prompt” “tardy”
Della Valle et al. 2005
Mannucci et al. 2005
Mannucci et al. 2006;
Sullivan et al. 2006
Aubourg et al. 2007
Phillips’s relationship is calibrated on the “tardy” component luminosity-decline rate relation might change with redshift??? Metallicity? (Nomoto et al. 2003
Dominguez et al. 2005)
bmaM dB 15
bmaM dB 15
Two scenarios for type Ia• Double degenarate: where two C-O WDs in
a binary systems make coalescence as result of the lost of orbital energy for GWs
(Webbink 1984; Iben & Tutukov 1984)
• Single Degenerate (Whelan & Iben 1973, Nomoto
1982) Cataclysmic-like systems: RNe (WD+giant, WD+He)
Symbiotic systems (WD+Mira or red giant)
Supersoft X-ray Sources (WD+MS star)
Both explosive channels are at play?
maybe at different redshifts?
• Extinction factor: AB =RB x E(B-V) for SNe-Ia in many cases RB 2-3 (Capaccioli et al. 1990, Della Valle & Panagia 1992, Phillips et al. 1999, Altavilla et al. 2004, Elias-Rosa et al. 2006, Wang et al. 2006)
more important at high-z
AKzDMm ML 25)];;(log[5
Is evolution or dust problem?
Leibundgut 2001
Origin of (possible) Supernova systematics
1. unknown explosion mechanism (z?)2. unknown progenitor systems (z?)3. light curve shape correction methods for the
luminosity normalisation may depend on z4. signatures of evolution in the colours? (z?)5. anomalous reddening law6. contaminations of the Hubble Diagram by no-standard SNe-Ia and/or bright SNe-Ibc (e.g.
HNe)
Tonry et al. 2003
Supernova cosmology
Wood-vasey 2006
If the “offset from the truth” is just 0.1 mag….
We need to carry out an independent measurement of m and the Hubble diagram for type Ia SNe is significantly affected by systematics
GRBs allow us today to change the “experimental methodology” and provide an independent measurement of the cosmological parameters
Scie
nce w
ith
S
cie
nce w
ith
ELTs
ELTs
GRBs Strengths
• GRBs are extremely bright detectable out of cosmological distances (z=6.3 Kuwai et
al. 2005, Tagliaferri et al. 2005) interesting objects for cosmology
• SNe-Ia are currently observed at z<1.7. Then GRBs appear to be (in principle) the only class of objects capable to study the evolution of the dark energy from the beginning (say from z~7-8)
• No correction for reddening
GRBs Chinks
• GRBs are not “genuine” standard candles E=1048-54erg (however also SNe-Ia need to be standardize)
• GRBs cannot be calibrated in the local universe (too few and the only ones observed are peculiar/sub-energetic)
In spite of these “drawbacks”, several attempts for standardizing GRBs with 3- or multi-parameters spectrum-energy correlations have been carried out
Ghirlanda et al. (2004), Firmani et al. (2006), Schaefer (2007)
They are (at least partially) model dependent. in the Ghirlanda relationship the third parameter, tbreak is assumed to be the signature of beaming for the GRB ejecta. This should be a common feature observable in all GRBs, but this is not true….
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 ?
Ep,i-E correlation need to clarify and understand the problem lack of chromatic breaks and possible outliers
GRB 061007, Mundell et al. Schady et al.
GRB 050416a
Very recently (Kodama et al., 2008; Liang et al., 2008) have calibrated the GRB spectrum—energy correlation at z < 1.7 by using SNe-Ia and they have obtained significant constraints on both M and (very similar to those obtained via SNe-Ia).
With this method GRBs are not indipendent cosmological rulers! In these works the basic assumption is that SNe-Ia are all the same at all z (which is just the point that one needs to verify!!! ).
“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 Ep,i-Eiso (Amati) correlation for cosmology
It is based on only 2 observables much higher number of GRB that can be used
Amati et al. 2008
70 GRB
GRB F spectra typically show a peak at photon energy Ep
for GRB with known redshift it is possible to estimate the cosmological rest frame peak energy Ep,i and the radiated energy assuming isotropic emission, Eiso
““Standardizing” GRB with spectrum-energy Standardizing” GRB with spectrum-energy correlationscorrelations
log(Ep,i )= 2.52 ,
= 0.43log(Eiso)= 1.0 ,
= 0.9
GRB Peak Energy
Characteristic energy of
most emitted photons
AKzDMm ML 25)];;(log[5
Using the Ep,i-Eiso correlation for cosmology
We find clear evidence that the observed scatter of the Ep,i-Eiso correlation
depends on the choice of cosmological parameters used to compute Eiso
In other words the observed dispersion is sensitive at varying the values of the
cosmological parameters
Amati et al. 2008
Simple PL fit70 GRB
Best fit M ~ 0.15Best fit M ~ 0.25
Maximum likelihood
i) Our analysis constrains M to 0.02-0.68 (90%).
ii) The current GRB sample provides weaker constraints on m than SNe-Ia. Nevertheless present and future GRB experiments (e.g., Swift, Konus_WIND, AGILE, GLAST, SVOM) are expected to make GRBs capable to measure (independently) m with an uncertainty similar to that provided by the current samples of SNe-Ia
Amati et al. 2008
70 REAL 70 REAL + 150 SIM.
Conclusions I
iii) for a flat universe (M = 1 excluded at 99.9% c.l.)
iv) Our approach does not make any assumption on the Ep-Eiso correlation and does not use any other calibrators to set the zero point of the relation, so it is free from “circular” arguments, our finding provides an independent evidence for the existence of a repulsive energy component (dark energy) which accounts for a large fraction of the energy density of the universe (see Amati et al. 2008 for more)
v) Releasing the assumption of a flat universe, we still find evidence for a low value of M (<0.50 at 68%) and ~ 1.05
vi) Significant constraints on the evolution of the dark energy with z are expected from both sample enrichment and z extension due to present and future GRB experiments
Conclusions II