The Second Stellar Spectrum: Rotating hot massive star linear spectropolarimetry with the Ohman Effect

TL;DR

This paper explores the Ohman effect in rotating hot massive stars, revealing a unique polarization signature in the FUV spectrum that can be observed with future space missions, providing new insights into stellar atmospheres.

Contribution

It introduces the theoretical prediction of the Ohman effect in stellar spectropolarimetry, highlighting its potential to reveal the second stellar spectrum in the FUV for rotating hot stars.

Findings

Triple-peak polarization pattern across lines

Polarization amplitude of 0.1% to 1% in FUV

Potential for future spaceborne spectropolarimetry

Abstract

To understand better the polarized radiative transfer near the surface of rotating massive stars that remain nearly spherically symmetric, we use plane-parallel stellar atmosphere models to explore the unique opportunity presented by the Ohman effect. This effect refers to the predicted variation in linear polarization across a rotationally broadened absorption line, due to the interaction of that line with the spatially varying continuum polarization across the face of a strongly scattering photosphere, such as found in hot stars. Even if the rotation is weak enough for the star to remain spherically symmetric, the Ohman effect persists because differential absorption induced by the rotational Doppler shift of the line breaks the symmetry that would otherwise cancel the continuum polarization in the absence of that line. Neglecting rotational distortion effects, the net polarization across the line vanishes, yet resolved line profiles display a telltale triple-peak polarization pattern, with one strong polarization peak at line center and two smaller ones in the line wings at a position angle that is rotated 90 degrees from the line center. The far ultraviolet (FUV) is emphasized because both the polarization amplitude and the specific luminosity are greatest there for photospheres with effective temperatures between about 15,000 and 20,000K. There is a high density of spectral lines in the FUV, leading to a rich "second stellar spectrum" in linear polarization (analogous to the "second solar spectrum") that is made observable with stellar rotation. Polarizations at the level of 0.1% to 1% are achievable across individual lines for a wide variety of B-type stars. We highlight the prospects for accessing the unique information encoded in the Ohman effect with future moderate-resolution spaceborne spectropolarimetric missions in the FUV.