Flows into inflation: An effective field theory approach

Author(s)

Azhar, Feraz; Kaiser, David I

Abstract

We analyze the flow into inflation for generic “single-clock” systems, by combining an effective field theory approach with a dynamical-systems analysis. In this approach, we construct an expansion for the potential-like term in the effective action as a function of time, rather than specifying a particular functional dependence on a scalar field. We may then identify fixed points in the effective phase space for such systems, order by order, as various constraints are placed on the Mth time derivative of the potential-like function. For relatively simple systems, we find significant probability for the background spacetime to flow into an inflationary state and for inflation to persist for at least 60 e-folds. Moreover, for systems that are compatible with single-scalar-field realizations, we find a single, universal functional form for the effective potential, V(ϕ), which is similar to the well-studied potential for power-law inflation. We discuss the compatibility of such dynamical systems with observational constraints.

Date issued

2018-09

URI

http://hdl.handle.net/1721.1/117764

Department

Massachusetts Institute of Technology. Department of Physics

Journal

Physical Review D

Publisher

American Physical Society

Citation

Azhar, Feraz and David I. Kaiser. "Flows into inflation: An effective field theory approach." Physical Review D 98, 6 (September 2018): 063515 © 2018 American Physical Society

Version: Final published version

ISSN

2470-0010

2470-0029