TY - JOUR
T1 - Polarization due to rotational distortion in the bright star Regulus
AU - Cotton, Daniel V.
AU - Bailey, Jeremy
AU - Howarth, Ian D.
AU - Bott, Kimberly
AU - Kedziora-Chudczer, Lucyna
AU - Lucas, P. W.
AU - Hough, J. H.
PY - 2017
Y1 - 2017
N2 - Polarization in stars was first predicted by Chandrasekhar 1, who calculated a substantial linear polarization at the stellar limb for a pure electron-scattering atmosphere. This polarization will average to zero when integrated over a spherical star but could be detected if the symmetry was broken, for example, by the eclipse of a binary companion. Nearly 50 years ago, Harrington and Collins 2 modelled another way of breaking the symmetry and producing net polarization-the distortion of a rapidly rotating hot star. Here we report the first detection of this effect. Observations of the linear polarization of Regulus, with two different high-precision polarimeters, range from +42 ppm at a wavelength of 741 nm to-22 ppm at 395 nm. The reversal from red to blue is a distinctive feature of rotation-induced polarization. Using a new set of models for the polarization of rapidly rotating stars, we find that Regulus is rotating at 96.5-0.8+0.6% 96. 5-0.8 + 0.6 % of its critical angular velocity for break-up, and has an inclination greater than 76.5°. The rotation axis of the star is at a position angle of 79.5 ± 0.7°. The conclusions are independent of, but in good agreement with, the results of previously published interferometric observations of Regulus 3. The accurate measurement of rotation in early-type stars is important for understanding their stellar environments 4 and the course of their evolution 5.
AB - Polarization in stars was first predicted by Chandrasekhar 1, who calculated a substantial linear polarization at the stellar limb for a pure electron-scattering atmosphere. This polarization will average to zero when integrated over a spherical star but could be detected if the symmetry was broken, for example, by the eclipse of a binary companion. Nearly 50 years ago, Harrington and Collins 2 modelled another way of breaking the symmetry and producing net polarization-the distortion of a rapidly rotating hot star. Here we report the first detection of this effect. Observations of the linear polarization of Regulus, with two different high-precision polarimeters, range from +42 ppm at a wavelength of 741 nm to-22 ppm at 395 nm. The reversal from red to blue is a distinctive feature of rotation-induced polarization. Using a new set of models for the polarization of rapidly rotating stars, we find that Regulus is rotating at 96.5-0.8+0.6% 96. 5-0.8 + 0.6 % of its critical angular velocity for break-up, and has an inclination greater than 76.5°. The rotation axis of the star is at a position angle of 79.5 ± 0.7°. The conclusions are independent of, but in good agreement with, the results of previously published interferometric observations of Regulus 3. The accurate measurement of rotation in early-type stars is important for understanding their stellar environments 4 and the course of their evolution 5.
UR - https://hdl.handle.net/1959.7/uws:78037
UR - https://www.proquest.com/scholarly-journals/polarization-due-rotational-distortion-bright/docview/2389674749/se-2?accountid=36155
U2 - 10.1038/s41550-017-0238-6
DO - 10.1038/s41550-017-0238-6
M3 - Article
SN - 2397-3366
VL - 1
SP - 690
EP - 696
JO - Nature Astronomy
JF - Nature Astronomy
IS - 10
ER -