Fast Winds and Mass Loss from Metal-Poor Field Giants

TL;DR

This study uses near-infrared spectra to detect fast stellar winds in metal-poor giants, revealing significant mass loss that impacts stellar evolution and globular cluster dynamics, driven likely by magnetic or hydrodynamic processes.

Contribution

First empirical measurement of mass loss rates in metal-poor giants and horizontal branch stars, linking stellar winds to evolutionary and cluster phenomena.

Findings

Fast outflows detected in most giants with speeds allowing escape.

Mass loss rates significant for stellar evolution, up to 6×10^-8 solar masses per year.

Wind-driven mass loss may influence horizontal branch morphology and intracluster material.

Abstract

Spectra of the He I 10830 Angstrom line were obtained with NIRSPEC on the Keck 2 telescope for metal-deficient field giant stars. This line is ubiquitous in stars with T_eff greater than 4500K and M_V fainter than -1.5. Fast outflows are detected from the majority of stars and about 40 percent of the outflows have sufficient speed to allow escape of material from the star as well as from a globular cluster. Outflow speeds and line strengths do not depend on metallicity suggesting the driving mechanism for these winds derives from magnetic and/or hydrodynamic processes. Gas outflows are present in every luminous giant, but are not detected in all stars of lower luminosity indicating possible variability. Mass loss rates ranging from 3X10(-10) to 6X10(-8) solar mass/yr estimated from the Sobolev approximation represent values with evolutionary significance for red giant branch (RGB) and red horizontal branch (RHB) stars. We estimate that 0.2 M_sun will be lost on the RGB, and the torque of this wind can account for observations of slowly rotating RHB stars in the field. About 0.1-0.2 M_sun will be lost on the RHB itself. This first empirical determination of mass loss on the RHB may contribute to the appearance of extended horizontal branches in globular clusters. The spectra appear to resolve the problem of missing intracluster material in globular clusters. Opportunities exist for 'wind smothering' of dwarf stars by winds from the evolved population, possibly leading to surface pollution in regions of high stellar density.