Adiabaticity and gravity theory independent conservation laws for cosmological perturbations

TL;DR

This paper explores how different definitions of adiabaticity affect the behavior and conservation of cosmological perturbations across various gravity theories and matter fields, highlighting conditions where standard conserved quantities may not hold.

Contribution

It derives a general relation linking lapse functions and non-adiabatic pressure perturbations, and demonstrates that adiabaticity alone does not guarantee conservation of key perturbation variables.

Findings

Uniform density, comoving, and proper-time slicings coincide if $c_s eq c_w$ and $ abla$ terms are negligible.

In general relativity, $R_c$ and $ zeta$ are conserved on superhorizon scales under adiabatic conditions.

Ultra slow-roll inflation shows non-conservation of $R_c$ and $ zeta$, emphasizing limits of adiabaticity for conservation laws.

Abstract

We carefully study the implications of adiabaticity for the behavior of cosmological perturbations. There are essentially three similar but different definitions of non-adiabaticity: one is appropriate for a thermodynamic fluid $\delta P_{nad}$, another is for a general matter field $\delta P_{c,nad}$, and the last one is valid only on superhorizon scales. The first two definitions coincide if $c_s^2=c_w^2$ where $c_s$ is the propagation speed of the perturbation, while $c_w^2=\dot P/\dot\rho$. Assuming the adiabaticity in the general sense, $\delta P_{c,nad}=0$, we derive a relation between the lapse function in the comoving sli\-cing $A_c$ and $\delta P_{nad}$ valid for arbitrary matter field in any theory of gravity, by using only momentum conservation. The relation implies that as long as $c_s\neq c_w$, the uniform density, comoving and the proper-time slicings coincide approximately for any gravity theory and for any matter field if $\delta P_{nad}=0$ approximately. In the case of general relativity this gives the equivalence between the comoving curvature perturbation $R_c$ and the uniform density curvature perturbation $\zeta$ on superhorizon scales, and their conservation. We then consider an example in which $c_w=c_s$, where $\delta P_{nad}=\delta P_{c,nad}=0$ exactly, but the equivalence between $R_c$ and $\zeta$ no longer holds. Namely we consider the so-called ultra slow-roll inflation. In this case both $R_c$ and $\zeta$ are not conserved. In particular, as for $\zeta$, we find that it is crucial to take into account the next-to-leading order term in $\zeta$'s spatial gradient expansion to show its non-conservation, even on superhorizon scales. This is an example of the fact that adiabaticity (in the thermodynamic sense) is not always enough to ensure the conservation of $R_c$ or $\zeta$.