XRISM Observation of the Supernova Remnant N103B: Velocity Structure and Thermal Properties

Abstract

We present the first analysis of the X-ray Imaging and Spectroscopy Mission (XRISM) observation of the supernova remnant (SNR) N103B. We fit the X-ray spectrum taken with the Resolve microcalorimeter, which captured emission lines from the predominantly ejecta elements Si, S, Ar, Ca, Cr, Mn, and Fe. Notably, our fits require a previously unidentified high-temperature, highly-ionized, Fe-dominated plasma component with particularly high Cr and Mn abundances, matching a feature also present in the recent XRISM analysis of the SNR N132D. We find that all ejecta in N103B exhibits significant line broadening arising mostly from thermal Doppler broadening: increasing from σ th1700 km s-1 for intermediate-mass element (IME: Si, S, Ar, and Ca) ejecta to 2800 km s-1 for Fe-rich ejecta. These velocities correspond to reverse shock velocities of 3500 and 5900 km s-1, respectively, in the ejecta frame of rest. Finally, we find that the IMEs are redshifted with a bulk velocity of 360 km s-1 while the Fe-dominated components are split: one redshifted at 1560 km s-1 and the other blueshifted at 1020 km s-1. Our results provide further support for the double-ring structure of N103B as it expands into the bipolar winds of a non-degenerate companion and highlight the strength of high-resolution spectroscopic observations of SNRs.