The dynamical viability of scalar-tensor gravity theories

TL;DR

This paper analyzes the dynamical behavior of scalar-tensor gravity theories, identifying conditions for cosmological evolution consistent with dark energy and matter-dominated eras, and classifies different evolutionary regimes.

Contribution

It provides a comprehensive framework for understanding the evolution of scalar-tensor theories in both Jordan and Einstein frames, including new classes of transitory acceleration.

Findings

Five classes of evolutionary behavior identified.

Four classes similar to f(R) theories, one unique to certain couplings.

Viable regions for late-time acceleration mapped in the (r,m) plane.

Abstract

We establish the dynamical attractor behavior in scalar-tensor theories of dark energy, providing a powerful framework to analyze classes of theories, predicting common evolutionary characteristics that can be compared against cosmological constraints. In the Jordan frame the theories are viewed as a coupling between a scalar field, \Phi, and the Ricci scalar, R, F(\Phi)R. The Jordan frame evolution is described in terms of dynamical variables m \equiv d\ln F/d\ln \Phi and r \equiv -\Phi F/f, where F(\Phi) = d f(\Phi)/d\Phi. The evolution can be alternatively viewed in the Einstein frame as a general coupling between scalar dark energy and matter, \beta. We present a complete, consistent picture of evolution in the Einstein and Jordan frames and consider the conditions on the form of the coupling F and \beta required to give the observed cold dark matter (CDM) dominated era that transitions into a late time accelerative phase, including transitory accelerative eras that have not previously been investigated. We find five classes of evolutionary behavior of which four are qualitatively similar to those for f(R) theories (which have \beta=1/2). The fifth class exists only for |\beta| < \sqrt{3}/4, i.e. not for f(R) theories. In models giving transitory late time acceleration, we find a viable accelerative region of the (r,m) plane accessible to scalar-tensor theories with any coupling, \beta (at least in the range |\beta| \leq 1/2, which we study in detail), and an additional region open only to theories with |\beta| < \sqrt{3}/4.