Reducing Zero-point Systematics in Dark Energy Supernova Experiments

A. Bonissent; A. Stebbins; A.G. Kim; Aldering; Amanullah; Astier; Branch; C. Stoughton; Cardelli; Copin; D. Gerdes; D. Tucker; Dawson; de Putter; E.V. Linder; G. Bernstein; G. Kushner; H. Shukla; Hicken; Hsiao; J. Christiansen; Kim; Kim; Kowalski; L. Faccioli; L. Gladney; Linder; Linder; Linder; M. Brown; N. Connolly; N. Mostek; Nordin; Perlmutter; Perlmutter; R. Miquel; Riess; S. Deustua; S. McKee; Samsing; W. Carithers; Wood-Vasey

research

Reducing Zero-point Systematics in Dark Energy Supernova Experiments

Authors: A. Bonissent
A. Stebbins
A.G. Kim
Aldering
Amanullah
Astier
Branch
C. Stoughton
Cardelli
Copin
D. Gerdes
D. Tucker
Dawson
de Putter
E.V. Linder
G. Bernstein
G. Kushner
H. Shukla
Hicken
Hsiao
J. Christiansen
Kim
Kim
Kowalski
L. Faccioli
L. Gladney
Linder
Linder
Linder
M. Brown
N. Connolly
N. Mostek
Nordin
Perlmutter
Perlmutter
R. Miquel
Riess
S. Deustua
S. McKee
Samsing
W. Carithers
Wood-Vasey
Publication date: 28 April 2010
Publisher: 'Elsevier BV'
Doi

Abstract

We study the effect of filter zero-point uncertainties on future supernova dark energy missions. Fitting for calibration parameters using simultaneous analysis of all Type Ia supernova standard candles achieves a significant improvement over more traditional fit methods. This conclusion is robust under diverse experimental configurations (number of observed supernovae, maximum survey redshift, inclusion of additional systematics). This approach to supernova fitting considerably eases otherwise stringent mission calibration requirements. As an example we simulate a space-based mission based on the proposed JDEM satellite; however the method and conclusions are general and valid for any future supernova dark energy mission, ground or space-based.Comment: 30 pages,8 figures, 5 table, one reference added, submitted to Astroparticle Physic