Plasma Dynamics of Radiative Cooling Accretion Flow in AM Herculis with XRISM

Abstract

We present XRISM/Resolve high-resolution X-ray spectroscopy of the prototypical magnetic cataclysmic variable AM Herculis. All satellite lines of highly ionized Fe are fully resolved. Lighter element lines (Si, S, Ca) show 2 - 3 eV widths consistent with purely thermal broadening, while the broader 6 - 7 eV Fe lines require additional bulk Doppler broadening. Spin-phase-resolved modulations are clearly detected in the Fe XXV and Fe XXVI lines, with semi-amplitudes of 81.86 km s-1 and 132.59 km s-1, and mean velocities of 143.66 km s-1 and 225.68 km s-1, respectively. After removing these bulk Doppler shifts, we obtain intrinsic Doppler widths of 5.23-0.15+0.16 eV for Fe XXV and 6.23-0.18+0.19 eV for Fe XXVI, directly revealing gradients of bulk velocity and temperature in the cooling-flow plasma. We additionally examined the resonance anisotropy predicted by Terada et al. (1999, 2001): the equivalent widths of the Fe XXV and Fe XXVI resonance lines increase at the pole-on phase by factors of 1.30 - 1.35, in positive correlation with their oscillator strengths. Combining XRISM with simultaneous NuSTAR data and PSAC/MCVSPEC plasma models, we derive a self-consistent shock temperature of 24.00.1 keV and shock velocity of 1,1162 km s-1. Radiative transfer simulations of the resonance lines further constrain the shock density to about (5 - 6)×1015 cm-3, providing a new density diagnostic for accretion columns. The resulting accretion column geometry has a height of 200 - 300 km and a radius of 200 - 400 km.