WD 1145+017: Alternative models of the atmosphere, dust clouds, and gas rings

TL;DR

This paper proposes alternative models for the dust clouds, gas rings, and atmospheric composition of WD 1145+017, explaining its variable circumstellar features and UV transits through radiative transfer simulations and spectral analysis.

Contribution

It introduces new dust cloud and gas disk models, and provides detailed atmospheric composition analysis, addressing limitations of previous models for WD 1145+017.

Findings

UV transits may be caused by dust grain phase functions and forward scattering.

The gaseous disk structure precesses with a period of approximately 3.83 years.

The star's atmosphere has a composition similar to CI chondrites, with some elements underabundant.

Abstract

WD 1145+017 is the first white dwarf known to be orbited by disintegrating exoasteroids. It is a DBZ-type white dwarf with strongly variable broad circumstellar lines and variable shallow UV transits. Various models of the dust clouds and gaseous rings have been proposed as an explanation for this behavior. Here we propose alternative models.The simple radiative transfer code Shellspec was modified for this purpose and used for testing the new dust cloud and gas disk models. We used modified TLUSTY and SYNSPEC codes to calculate atmosphere models assuming the LTE or NLTE, and to calculate the intrinsic spectrum of the star. We then used these atmosphere models to estimate the mass of the radiative and convective zones and NLTE spectrum synthesis to estimate their chemical composition. We offer an alternative explanation of some (not all) shallow UV transits. These may be naturally caused by the optical properties of the dust grains: opacities and mainly phase functions as a result of the forward scattering. The latter is much stronger in UV compared to the optical region, leaving more UV photons in the original direction during the transit. We also developed an alternative model of the gaseous disk, consisting of an inner, hotter, and almost circular disk and an outer, cooler, and eccentric disk. The structure precesses with a period of $3.83 \pm 0.12$ yr. We demonstrate that it fits the observed circumstellar lines reasonably well. These alternative models solve a few drawbacks that might be associated with the previous models, but they also have their own disadvantages. We confirm that the chemical composition of the atmosphere is similar to that of CI chondrites but C, N, and S are significantly underabundant and much closer to the bulk Earth composition. This is a strong argument that the star has recently encountered and accreted material from a body of Earth-like composition.