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Adam G. Riess Johns Hopkins University and Space Telescope Science Institute The History of Cosmic Expansion from Supernovae Near and Far.

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Presentation on theme: "Adam G. Riess Johns Hopkins University and Space Telescope Science Institute The History of Cosmic Expansion from Supernovae Near and Far."— Presentation transcript:

1 Adam G. Riess Johns Hopkins University and Space Telescope Science Institute The History of Cosmic Expansion from Supernovae Near and Far

2 What we see Type Ia Supernovae Homogeneous:1.4 M sun, 10 51 ergs,a few 10 10 L sun Can be seen halfway across the visible Universe

3 By 1998 two teams measured >100 SNe Ia at 0.01 <z<1.0 Surprise! The Universe is accelerating, propelled by dark energy. High-z SCP The Accelerating Universe

4 Hubble Higher-z Team Awarded 134 (+399 with GOODS) orbits in 2002-2003, 90 orbits in 2003-2004 and 270 Orbits in 2004-2005 P.I. Riess (STScI), Ferguson(STScI) Strolger (STScI), Tonry (UH) Filippenko (UCB), Jha (UCB), Li (UCB), Kirshner, (CfA) Challis, (CfA), Casertano, (STScI) Dickinson (STScI),Giavalisco (STScI) Livio (STScI),Mobasher (STScI) Using HST, find and measure type Ia supernovae at 0.9<z<1.7 To look for evidence of preceding deceleration (i.e., confirm dark energy) Characterize the nature of dark energy (i.e., its equation of state, w=p/  ) Innovations Required: ToO without spectral confirmation via color selection, host phot-z’s, U-band LC, grism spectroscopy with HST (Riess et al. 2003)

5 Our first higher-z SN Ia, Aphrodite Aphrodite (z=1.3) ACS grism spectrum NICMOS F110W ACS F850lp viz Highest z spectrum of a SN

6 In our HST program we already found in the past 3 cycles 135 SNe of all types, ~50 SNe Ia, ~25 SNe Ia at z>1 ~10 SN Ia in Elliptical Hosts (low dust content) with 0.9<z<1.7 Ferguson z=1.0 Vilas z=0.9 Thames z=1.0 97ff z=1.7 Sasquatch z=1.4 Thoth z=1.3 Lancaster z=1.2 Redford z=1.2 Ramone z=1.0

7 The New SN Ia Hubble Diagram (Riess et al. 2004) 97ff 2005: 19 of the 20 highest Redshift SNe known 6 of the 7 highest redshift SNe Ia (2003)

8 High Redshift SN and Expansion History Fainter Brighter 1.0 0.5 0.0 -0.5 Relative Brightness (  m) 0.00.51.01.52.0 Redshift z Freely expanding Constant deceleration Acceleration/ Deceleration Constant acceleration presentpast Freely expanding Constant deceleration Constant acceleration (or astrophysical dimming) Taylor Expansion of the left handside of the Friedman Eq: a(t)=f(t,H,q,j,…) q 0 =-, j 0 =0 q 0 =+, j 0 =0 q 0 =-, j 0 =+ q(z)=0 Dark Energy Dominated Dark Matter Dominated

9 Probing Dark Energy We have doubled our knowledge of w 0 and w’ in 1 year with HST Einstein’s model now looks better than ever, We should double our current progress again in upcoming publication of latest SNe…stay tuned! Two fundamental properties/clues of dark energy: its strength, w 0 =w(z=0) AND is it dynamic or static, i.e. is w’=dw/dz=0? Einstein’s w0w0 w0w0 W’

10 Two SN-based Routes to Constraining Dark Energy More SNe IaMore precise H 0 updating SN Ia M V,B calibration replace LMC with NGC4258 P-L “Single most important complement to the CMB for measuring the dark energy equation of state is a determination of the Hubble Constant to better than a few percent.” Wayne Hu, astro-ph 0407158 Projected ESSENCE 5 yrs

11 Not your Grandfather’s SN-Calibration of H 0 from 1937C! ACS Provides for a Reliable Recalibration of H 0 from Modern SNe Ia With HST we are now calibrating 4 from 1990’s and 2000’s Ground: SN 1994ae ACS: Cepheids

12 A New Approach to Taming Possible SN Ia Evolution in JDEM SN-Dark Energy Studies (Riess and Livio, in prep) JDEM mission concepts (e.g., SNAP) propose to average 1000’s of SNe Ia at 0<z<1.5 to measure the eq. of state of DE Such measurements will rely on our ability to detect and calibrate possible SN Ia evolution to ~1% A powerful method to do this is to observe SNe Ia at even higher redshifts, 1.5<z<3.0, where sensitivity to evolution is increased (e.g., global metallicity evolves by at least as much as at z<1.5, Kulkarni et al. 2005) and sensitivity to dark energy is decreased Such observations require flux measurements at 25<H & K<27 mag, well within reach of JWST, JWST should be able to measure 100’s such SNe Ia Dark Energy Sensitive Dark Energy Insensitive

13 Summary: SNe Ia are being used to trace the history of cosmic expansion; they reveal present, cosmic acceleration and the need for dark energy With HST we have discovered the highest redshift SNe Ia; they show a preceding epoch of decelerating expansion (as expected), confirming the reality of acceleration With growing precision, SNe Ia at all redshifts are being used to Determine the equation of state of dark energy (value and derivative) and should, in the future, help determine the nature of Dark Energy and perhaps the fate of the Universe. Additional studies of SNe Ia locally to improve the calibration of H 0 and at the ever higher redshifts to tame evolution are important for continued progress in Dark Energy studies

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