# Cyclotron resonant scattering feature simulations. II. Description of   the CRSF simulation process

**Authors:** F.-W. Schwarm (1), R. Ballhausen (1), S. Falkner (1), G. Sch\"onherr, (2), K. Pottschmidt (3, 4), M. T. Wolff (5), P. A. Becker (6), F. F\"urst, (7), D. M. Marcu-Cheatham (3, 4), P. B. Hemphill (8), E. Sokolova-Lapa (9, and 10), T. Dauser (1), D. Klochkov (11), C. Ferrigno (12), J. Wilms (1) ((1), Remeis-Observatory, ECAP, Univ. Erlangen, (2) AIP, (3) CRESST, UMBC, (4), NASA-GSFC, (5) NRL, (6) George Mason Univ., (7) ESA-ESAC, (8) MKI, MIT, (9), Faculty of Physics, Moscow State University, (10) Sternberg Astronomical, Institute, (11) IAAT, University of T\"ubingen, (12) ISDC, Universit\'e de, Gen\`eve)

arXiv: 1701.07669 · 2017-05-10

## TL;DR

This paper introduces a new, versatile Monte Carlo simulation code for modeling cyclotron resonant scattering features in X-ray pulsars, enabling complex geometry investigations and improved data interpretation.

## Contribution

The paper presents a novel, flexible simulation tool for CRSF modeling that overcomes previous geometric limitations and facilitates detailed spectral analysis.

## Key findings

- The code successfully simulates complex CRSF geometries.
- It produces Green's functions for arbitrary continuum spectra.
- Application to NuSTAR data demonstrates effective spectral fitting.

## Abstract

Cyclotron resonant scattering features (CRSFs) are formed by scattering of X-ray photons off quantized plasma electrons in the strong magnetic field (of the order 10^12 G) close to the surface of an accreting X-ray pulsar. The line profiles of CRSFs cannot be described by an analytic expression. Numerical methods such as Monte Carlo (MC) simulations of the scattering processes are required in order to predict precise line shapes for a given physical setup, which can be compared to observations to gain information about the underlying physics in these systems.   A versatile simulation code is needed for the generation of synthetic cyclotron lines. Sophisticated geometries should be investigatable by making their simulation possible for the first time.   The simulation utilizes the mean free path tables described in the first paper of this series for the fast interpolation of propagation lengths. The code is parallelized to make the very time consuming simulations possible on convenient time scales. Furthermore, it can generate responses to mono-energetic photon injections, producing Green's functions, which can be used later to generate spectra for arbitrary continua.   We develop a new simulation code to generate synthetic cyclotron lines for complex scenarios, allowing for unprecedented physical interpretation of the observed data. An associated XSPEC model implementation is used to fit synthetic line profiles to NuSTAR data of Cep X-4. The code has been developed with the main goal of overcoming previous geometrical constraints in MC simulations of CRSFs. By applying this code also to more simple, classic geometries used in previous works, we furthermore address issues of code verification and cross-comparison of various models. The XSPEC model and the Green's function tables are available online at http://www.sternwarte.uni-erlangen.de/research/cyclo .

## Full text

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## Figures

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## References

65 references — full list in the complete paper: https://tomesphere.com/paper/1701.07669/full.md

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