Evidence for a high-energy tail in the gamma-ray spectra of globular clusters

TL;DR

This study provides evidence for a high-energy tail in the gamma-ray spectra of globular clusters, indicating the presence of inverse Compton emission from relativistic particles, and distinguishes it from curvature radiation.

Contribution

It uncovers a significant power-law component in gamma-ray spectra of globular clusters, supporting the role of inverse Compton emission from millisecond pulsar-accelerated particles.

Findings

Detection of an 8.2σ power-law component in gamma-ray spectra.

Correlation between gamma-ray luminosity and photon field energy density.

Comparable luminosity of inverse Compton and curvature components.

Abstract

Millisecond pulsars are very likely the main source of gamma-ray emission from globular clusters. However, the relative contributions of two separate emission processes--curvature radiation from millisecond pulsar magnetospheres vs. inverse Compton emission from relativistic pairs launched into the globular cluster environment by millisecond pulsars--have long been unclear. To address this, we search for evidence of inverse Compton emission in 8-year $\textit{Fermi}$-LAT data from the directions of 157 Milky Way globular clusters. We find a mildly statistically significant (3.8$\sigma$) correlation between the measured globular cluster gamma-ray luminosities and their photon field energy densities. However, this may also be explained by a hidden correlation between the photon field densities and the stellar encounter rates of globular clusters. Analysed $\textit{in toto}$, we demonstrate that the gamma-ray emission of globular clusters can be resolved spectrally into two components: i) an exponentially cut-off power law and ii) a pure power law. The latter component--which we uncover at a significance of 8.2$\sigma$--has a power index of 2.79 $\pm$ 0.25. It is most naturally interpreted as inverse Compton emission by cosmic-ray electrons and positrons injected by millisecond pulsars. We find the luminosity of this power-law component is comparable to, or slightly smaller than, the luminosity of the curved component, suggesting the fraction of millisecond pulsar spin-down luminosity into relativistic leptons is similar to the fraction of the spin-down luminosity into prompt magnetospheric radiation.