New Early Dark Energy is compatible with current LSS data

TL;DR

This paper investigates the compatibility of New Early Dark Energy (NEDE) models with current large-scale structure data, using the effective field theory of LSS, and finds that NEDE remains consistent with observational constraints.

Contribution

The study applies the effective field theory of LSS to derive constraints on NEDE, demonstrating its compatibility with current observational data.

Findings

NEDE is compatible with current LSS, CMB, BAO, and SN data.

Including full-shape LSS data does not significantly alter the H0 estimate.

EFT of LSS favors NEDE, supporting its viability.

Abstract

Recently a full-shape analysis of large-scale structure (LSS) data was employed to provide new constraints on a class of Early Dark Energy (EDE) models. In this note, we derive similar constraints on New Early Dark Energy (NEDE) using the publicly available PyBird code, which makes use of the effective field theory of LSS. We study the NEDE base model with the fraction of NEDE and the trigger field mass as two additional parameters allowed to vary freely while making simplifying assumptions about the decaying fluid sector. Including the full-shape analysis of LSS together with measurements of the cosmic microwave background (CMB), baryonic acoustic oscillations (BAO) and supernovae (SN) data, we report $ H_0= 71.2 \pm 1.0~\textrm{km}\, \textrm{s}^{-1}\, \textrm{Mpc}^{-1}$ ($68 \%$ C.L.) together with a $\simeq 4 \, \sigma$ evidence for a non-vanishing fraction of NEDE. This is an insignificant change to the value previously found without full-shape LSS data, $ H_0= 71.4 \pm 1.0~\textrm{km}\, \textrm{s}^{-1}\, \textrm{Mpc}^{-1} $ ($68 \%$ C.L.). As a result, while the NEDE fit cannot be improved upon the inclusion of additional LSS data, it is also not adversely affected by it, making it compatible with current constraints from LSS data. In fact, we find evidence that the effective field theory of LSS acts in favor of NEDE.