Convective dynamos of black widow companions

TL;DR

This paper investigates how intense irradiation affects the internal structure and magnetic activity of black widow companion stars, altering their evolution and explaining observed binary systems.

Contribution

It introduces a model showing that strong irradiation suppresses convection, weakens magnetic fields, and modifies binary evolution, aligning theoretical predictions with observations.

Findings

Strong irradiation inhibits convection in companion stars.

Weaker magnetic fields result from suppressed convection, halting binary evolution.

The model explains the diversity of observed black widow and redback systems.

Abstract

Black widows and redbacks are binary millisecond pulsars with close low-mass companions that are irradiated and gradually ablated by the pulsar's high-energy luminosity $L_{\rm irr}$. These binaries evolve primarily through magnetic braking, which extracts orbital angular momentum and pushes the companion to overflow its Roche lobe. Here, we use the stellar evolution code MESA to examine how the irradiation modifies the companion's structure. Strong $L_{\rm irr}$ inhibits convection to the extent that otherwise fully convective stars become almost fully radiative. By computing the convective velocities and assuming a dynamo mechanism, we find that the thin convective envelopes of such strongly irradiated companions ($L_{\rm irr}\gtrsim 3\,{\rm L}_\odot$) generate much weaker magnetic fields than previously thought - halting binary evolution. With our improved magnetic braking model, we explain most observed black widow and redback companions as remnants of main-sequence stars. We also apply our model (with $L_{\rm irr}$) to evolved companions that overflow their Roche lobe close to the end of their main-sequence phase. The evolutionary tracks of such companions bifurcate, explaining the shortest period systems (which are potential gravitational wave sources) as well as the longest period ones (which are the progenitors of common pulsar-white dwarf binaries). The variety of black widow structures and evolutionary trajectories may be utilized to calibrate the dependence of magnetic braking on the size of the convective layer and on the existence of a radiative-convective boundary, with implications for single stars as well as other binaries, such as cataclysmic variables and AM Canum Venaticorum stars.