Millinovae: A New Class of Transient Supersoft X-ray Sources without a Classical Nova Eruption

TL;DR

This paper reports the discovery of a new class of transient supersoft X-ray sources, called millinovae, characterized by long optical outbursts and X-ray emission without classical nova eruptions, expanding understanding of white dwarf accretion phenomena.

Contribution

The study introduces millinovae, a novel class of transient supersoft X-ray sources, identified through optical and X-ray observations, lacking classical nova signatures.

Findings

29 new millinovae identified in the Magellanic Clouds

Detected transient supersoft X-rays during optical outbursts

No evidence of mass ejection typical of classical novae

Abstract

Some accreting binary systems containing a white dwarf (such as classical novae or persistent supersoft sources) are seen to emit low-energy X-rays with temperatures of ~10^6 K and luminosities exceeding 10^35 erg/s. These X-rays are thought to originate from nuclear burning on the white dwarf surface, either caused by a thermonuclear runaway (classical novae) or a high mass-accretion rate that sustains steady nuclear burning (persistent sources). The discovery of transient supersoft X-rays from ASASSN-16oh challenged these ideas, as no clear signatures of mass ejection indicative of a classical nova eruption were detected, and the origin of these X-rays remains controversial. It was unclear whether this star was one of a kind or representative of a larger, as yet undiscovered, group. Here, we present the discovery of 29 stars located in the direction of the Magellanic Clouds exhibiting long-duration, symmetrical optical outbursts similar to that seen in ASASSN-16oh. We observed one of these objects during an optical outburst and found it to be emitting transient supersoft X-rays, while no signatures of mass ejection (indicative of a classical nova eruption) were detected. We therefore propose that these objects form a homogeneous group of transient supersoft X-ray sources, which we dub ``millinovae'' because their optical luminosities are approximately a thousand times fainter than those of ordinary classical novae.