Fe Kα equivalent-width mapping with 3D radiative transfer calculation: A general model and application to the RS Canum Venaticorum-type stars with XRISM/Resolve

Abstract

The Fe K α fluorescence line at 6.4 keV has long been used to probe the relative geometry between photoionizing X-ray sources and surrounding cold material in a wide range of astrophysical systems. With the advent of the X-ray microcalorimeter XRISM/Resolve, Fe K α lines with equivalent widths down to 5 eV-previously inaccessible-are now detectable, and even non-detections can place upper limits of a few eV, making non-detections themselves valuable for constraining the geometry. Considering that Fe K α-based geometric diagnostics are entering a new stage in the microcalorimeter era, we present Fe K α equivalent-width maps computed with the three-dimensional Monte Carlo radiative-transfer code SKIRT for a generalized configuration consisting of a spherical reflector of radius R* and a point source located at a height h above the surface. The equivalent-width maps exhibit two characteristic features: (1) an increase toward the center of the projected surface of the sphere; and (2) an overall decrease with increasing h/R*. The key point is that we confirm these features for equivalent widths of < 40 eV, a regime that has become accessible for the first time thanks to the improved detection threshold from 50 eV with Chandra/HETG to 5 eV with XRISM/Resolve. As an illustrative application, we compare the maps with XRISM/Resolve spectra of three RS Canum Venaticorum-type stars (GT Muscae, σ Geminorum, and HR 1099) and constrain the locations of the flare loop and coronal bright points in these systems. Because the maps are constructed for a highly generalized point-source--spherical-reflector geometry, they are readily applicable to many other objects, including X-ray binaries and cataclysmic variables.