Gas and Cosmic-Ray Properties in the MBM 53, 54, and 55 Molecular Clouds and the Pegasus Loop as Revealed by HI Line Profiles, Dust, and Gamma-Ray Data

TL;DR

This study decomposes interstellar gas components using HI line profiles and dust data to analyze gamma-ray emissions, revealing a spectral break at 7 GeV and aligning gamma-ray and cosmic-ray spectra.

Contribution

It introduces a detailed gas component decomposition method and combines gamma-ray and cosmic-ray data to better understand interstellar medium properties.

Findings

Identified a spectral break in the interstellar proton spectrum at ~7 GeV.

Found the gamma-ray emissivity normalization agrees within 10% with AMS-02 proton spectrum.

Reconciled gamma-ray and cosmic-ray spectra, reducing previous tensions.

Abstract

In studying the interstellar medium (ISM) and Galactic cosmic rays (CRs), uncertainty of the interstellar gas density has always been an issue. To overcome this difficulty, we used a component decomposition of the 21-cm HI line emission and used the resulting gas maps in an analysis of $\gamma$-ray data obtained by the Fermi Large Area Telescope (LAT) for the MBM~53, 54, and 55 molecular clouds and the Pegasus loop. We decomposed the ISM gas into intermediate-velocity clouds, narrow-line and optically thick HI, broad-line and optically thin HI, CO-bright H2, and CO-dark H2 using detailed correlations with the HI line profiles from the HI4PI survey, the Planck dust-emission model, and the Fermi-LAT $\gamma$-ray data. We found the fractions of optical depth correction to the HI column density and CO-dark H2 to be nearly equal. We fitted the CR spectra directly measured at/near the Earth and the measured $\gamma$-ray emissivity spectrum simultaneously. We obtained a spectral break in the interstellar proton spectrum at ${\sim}$7~GeV, and found the $\gamma$-ray emissivity normalization agrees with the AMS-02 proton spectrum within 10\%, relaxing the tension with the CR spectra previously claimed.