The various accretion modes of AM Herculis: Clues from multi-wavelength observations in high accretion states

TL;DR

This study uses multi-wavelength X-ray and optical observations to explore different accretion modes in AM Herculis, revealing distinct behaviors in soft and hard X-ray emissions, accretion footpoint migration, and evidence of Compton reflection.

Contribution

It provides new insights into the accretion geometry and spectral features of AM Herculis in high states, including soft X-ray extinction and reflection signatures, with detailed phase-dependent analysis.

Findings

Soft X-ray emission assigned to a second pole during self-eclipse.

Detection of Compton reflection and Fe line at 6.4 keV.

Extended UV dips and absorption features observed.

Abstract

We report on XMM-Newton and NuSTAR X-ray observations of the prototypical polar, AM Herculis, supported by ground-based photometry and spectroscopy, all obtained in high accretion states. In 2005, AM Herculis was in its regular mode of accretion, showing a self-eclipse of the main accreting pole. X-ray emission during the self-eclipse was assigned to a second pole through its soft X-ray emission and not to scattering. In 2015, AM Herculis was in its reversed mode with strong soft blobby accretion at the far accretion region. The blobby acretion region was more luminous than the other, persistently accreting, therefore called main region. Hard X-rays from the main region did not show a self-eclipse indicating a pronounced migration of the accretion footpoint. Extended phases of soft X-ray extinction through absorption in interbinary matter were observed for the first time in AM Herculis. The spectral parameters of a large number of individual soft flares could be derived. Simultaneous NuSTAR observations in the reversed mode of accretion revealed clear evidence for Compton reflection of radiation from the main pole at the white dwarf surface. This picture is supported by the trace of the Fe resonance line at 6.4 keV through the whole orbit. Highly ionized oxygen lines observed with the Reflection Grating Spectrometer (RGS) were tentatively located at the bottom of the accretion column, although the implied densities are quite different from expectations. In the regular mode of accretion, the phase-dependent modulations in the ultraviolet (UV) are explained with projection effects of an accretion-heated spot at the prime pole. In the reversed mode projection effects cannot be recognized. The light curves reveal an extra source of UV radiation and extended UV absorbing dips. An Ha Doppler map obtained contemporaneously (abstract abridged)