Quintessence in a quandary: prior dependence in dark energy models

David J. E. Marsh; Philip Bull; Pedro G. Ferreira; Andrew Pontzen

doi:10.1103/PhysRevD.90.105023

Quintessence in a quandary: prior dependence in dark energy models

David J. E. Marsh, Philip Bull, Pedro G. Ferreira, Andrew Pontzen

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Abstract

The archetypal theory of dark energy is quintessence: a minimally coupled scalar field with a canonical kinetic energy and potential. By studying random potentials we show that quintessence imposes a restricted set of priors on the equation of state of dark energy. Focusing on the commonly-used parametrisation, w(a) w0+wa(1-a), we show that there is a natural scale and direction in the (w0, wa) plane that distinguishes quintessence as a general framework. We calculate the expected information gain for a given survey and show that, because of the non-trivial prior information, it is a function of more than just the figure of merit. This allows us to make a quantitative case for novel survey strategies. We show that the scale of the prior sets target observational requirements for gaining significant information. This corresponds to a figure of merit FOM 200, a requirement that future galaxy redshift surveys will meet.

Original language	English
Article number	105023
Pages (from-to)	1-6
Number of pages	6
Journal	Physical Review D
Volume	90
Issue number	10
DOIs	https://doi.org/10.1103/PhysRevD.90.105023
Publication status	Published - 18 Nov 2014

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10.1103/PhysRevD.90.105023

1406.2301v2

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@article{d4573cf9e74742ea90e696ae4a9574db,

title = "Quintessence in a quandary: prior dependence in dark energy models",

abstract = "The archetypal theory of dark energy is quintessence: a minimally coupled scalar field with a canonical kinetic energy and potential. By studying random potentials we show that quintessence imposes a restricted set of priors on the equation of state of dark energy. Focusing on the commonly-used parametrisation, w(a) w0+wa(1-a), we show that there is a natural scale and direction in the (w0, wa) plane that distinguishes quintessence as a general framework. We calculate the expected information gain for a given survey and show that, because of the non-trivial prior information, it is a function of more than just the figure of merit. This allows us to make a quantitative case for novel survey strategies. We show that the scale of the prior sets target observational requirements for gaining significant information. This corresponds to a figure of merit FOM 200, a requirement that future galaxy redshift surveys will meet. ",

author = "Marsh, {David J. E.} and Philip Bull and Ferreira, {Pedro G.} and Andrew Pontzen",

note = "5 pages, 3 figures. For the busy reader, Fig. 1 is the money plot. v2: Minor changes, matches published version. Code open source at gitorious.org/random-quintessence",

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doi = "10.1103/PhysRevD.90.105023",

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T2 - prior dependence in dark energy models

AU - Marsh, David J. E.

AU - Bull, Philip

AU - Ferreira, Pedro G.

AU - Pontzen, Andrew

N1 - 5 pages, 3 figures. For the busy reader, Fig. 1 is the money plot. v2: Minor changes, matches published version. Code open source at gitorious.org/random-quintessence

PY - 2014/11/18

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N2 - The archetypal theory of dark energy is quintessence: a minimally coupled scalar field with a canonical kinetic energy and potential. By studying random potentials we show that quintessence imposes a restricted set of priors on the equation of state of dark energy. Focusing on the commonly-used parametrisation, w(a) w0+wa(1-a), we show that there is a natural scale and direction in the (w0, wa) plane that distinguishes quintessence as a general framework. We calculate the expected information gain for a given survey and show that, because of the non-trivial prior information, it is a function of more than just the figure of merit. This allows us to make a quantitative case for novel survey strategies. We show that the scale of the prior sets target observational requirements for gaining significant information. This corresponds to a figure of merit FOM 200, a requirement that future galaxy redshift surveys will meet.

AB - The archetypal theory of dark energy is quintessence: a minimally coupled scalar field with a canonical kinetic energy and potential. By studying random potentials we show that quintessence imposes a restricted set of priors on the equation of state of dark energy. Focusing on the commonly-used parametrisation, w(a) w0+wa(1-a), we show that there is a natural scale and direction in the (w0, wa) plane that distinguishes quintessence as a general framework. We calculate the expected information gain for a given survey and show that, because of the non-trivial prior information, it is a function of more than just the figure of merit. This allows us to make a quantitative case for novel survey strategies. We show that the scale of the prior sets target observational requirements for gaining significant information. This corresponds to a figure of merit FOM 200, a requirement that future galaxy redshift surveys will meet.

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JO - Physical Review D

JF - Physical Review D

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ER -

Quintessence in a quandary: prior dependence in dark energy models

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