Constraining the Cosmic-ray Energy Based on Observations of Nearby Galaxy Clusters by LHAASO

TL;DR

This study used LHAASO observations to set upper limits on gamma-ray emissions from nearby galaxy clusters, constraining the energy of cosmic rays and informing models of cosmic-ray acceleration in cluster shocks.

Contribution

First to analyze LHAASO data for diffuse gamma-ray emission in galaxy clusters, providing new constraints on cosmic-ray energy and acceleration mechanisms.

Findings

No significant diffuse gamma-ray emission detected.

Established upper limits on gamma-ray flux for three clusters.

Derived constraints on cosmic-ray proton energy above 10 TeV.

Abstract

Galaxy clusters act as reservoirs of high-energy cosmic rays (CRs). As CRs propagate through the intracluster medium, they generate diffuse $\gamma$-rays detectable by arrays such as LHAASO. These $\gamma$-rays result from proton-proton ($pp$) collisions of very high-energy cosmic rays (VHECRs) or inverse Compton (IC) scattering of positron-electron pairs created by $p\gamma$ interactions of ultra-high-energy cosmic rays (UHECRs). We analyzed diffuse $\gamma$-ray emission from the Coma, Perseus, and Virgo clusters using LHAASO data. Diffuse emission was modeled as a disk of radius $R_{500}$ for each cluster while accounting for point sources. No significant diffuse emission was detected, yielding 95\% confidence level (C.L.) upper limits on the $\gamma$-ray flux: for WCDA (1-25~TeV) and KM2A ($>25$~TeV), less than $(49.4, 13.7, 54.0)$ and $(1.34, 1.14, 0.40) \times 10^{-14}$~ph~cm$^{-2}$~s$^{-1}$ for Coma, Perseus, and Virgo, respectively. The $\gamma$-ray upper limits can be used to derive model-independent constraints on the integral energy of CRp above 10~TeV (corresponding to the LHAASO observational range $>1$~TeV under the $pp$ scenario) to be less than $(1.96, 0.59, 0.08) \times 10^{61}$~erg. The absence of detectable annuli/ring-like structures, indicative of cluster accretion or merging shocks, imposes further constraints on models in which the UHECRs are accelerated in the merging shocks of galaxy clusters.