Observational Constraints on Teleparallel Dark Energy

A. Unzicker; C. Xu; C.G. Boehmer; Chao-Qiang Geng; Chung-Chi Lee; D.J. Eisenstein; Emmanuel N Saridakis; H. Wei; H. Wei; J.B. Dent; J.R. Bond; K. Bamba; K. Bamba; K. Bamba; K.K. Yerzhanov; M.H. Daouda; M.R. Setare; R. Amanullah .; R. Gannouji; R. Weitzenböck; R. Zheng; R.-J. Yang; R.-X. Miao; SDSS collaboration; Supernova Cosmology Project collaboration; Supernova Search Team collaboration; W. Hu; WMAP collaboration; WMAP collaboration; X.-m. Chen; Y. Zhang; Y.-F. Cai

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Observational Constraints on Teleparallel Dark Energy

Authors: A. Unzicker
C. Xu
C.G. Boehmer
Chao-Qiang Geng
Chung-Chi Lee
D.J. Eisenstein
Emmanuel N Saridakis
H. Wei
H. Wei
J.B. Dent
J.R. Bond
K. Bamba
K. Bamba
K. Bamba
K.K. Yerzhanov
M.H. Daouda
M.R. Setare
R. Amanullah .
R. Gannouji
R. Weitzenböck
R. Zheng
R.-J. Yang
R.-X. Miao
SDSS collaboration
Supernova Cosmology Project collaboration
Supernova Search Team collaboration
W. Hu
WMAP collaboration
WMAP collaboration
X.-m. Chen
Y. Zhang
Y.-F. Cai
Publication date: 6 December 2011
Publisher: 'IOP Publishing'
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Abstract

We use data from Type Ia Supernovae (SNIa), Baryon Acoustic Oscillations (BAO), and Cosmic Microwave Background (CMB) observations to constrain the recently proposed teleparallel dark energy scenario based on the teleparallel equivalent of General Relativity, in which one adds a canonical scalar field, allowing also for a nonminimal coupling with gravity. Using the power-law, the exponential and the inverse hyperbolic cosine potential ansatzes, we show that the scenario is compatible with observations. In particular, the data favor a nonminimal coupling, and although the scalar field is canonical the model can describe both the quintessence and phantom regimes.Comment: 19 pages, 6 figures, version accepted by JCA

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