Scars of Intense Accretion Episodes at Metal-Rich White Dwarfs

TL;DR

This paper suggests that intense, short-lived accretion episodes of gas onto metal-rich white dwarfs can explain observed discrepancies in accretion rates, with implications for understanding debris composition and accretion models.

Contribution

It introduces the idea that brief, high-rate accretion events account for the historical accretion rates in white dwarfs, challenging steady-state assumptions.

Findings

High accretion rates (~1e15 g/s) are possible during brief episodes.

Gaseous debris from tidal disruptions can cause rapid accretion.

Particulate disks contribute to long-term, lower accretion rates.

Abstract

A re-evaluation of time-averaged accretion rates at DBZ-type white dwarfs points to historical, time-averaged rates significantly higher than the currently observed episodes at their DAZ counterparts. The difference between the ongoing, instantaneous accretion rates witnessed at DAZ white dwarfs, which often exceed 1e8 g/s, and those inferred over the past 1e5-1e6 yr for the DBZ stars can be a few orders of magnitude, and therefore must result from high-rate episodes of tens to hundreds of years so they remain undetected to date. This paper explores the likelihood that such brief, intense accretion episodes of gas-phase material can account for existing data. For reasonable assumptions about the circumstellar gas, accretion rates approaching or exceeding 1e15 g/s are possible, similar to rates observed in quiescent cataclysmic variables, and potentially detectable with future x-ray missions or wide-field monitoring facilities. Gaseous debris that is prone to such rapid accretion may be abundant immediately following a tidal disruption event via collisions and sublimation, or if additional bodies impinge upon an extant disk. Particulate disk matter accretes at or near the Poynting-Robertson drag rate for long periods between gas-producing events, consistent with rates inferred for dusty DAZ white dwarfs. In this picture, warm DAZ stars without infrared excesses have rates consistent with accretion from particulate disks that remain undetected. This overall picture has implications for quasi-steady state models of accretion and the derived chemical composition of asteroidal debris in DBZ white dwarfs.