First Detection of Circular Polarization in Radio Continuum Toward a Massive Protostar

The Astrophysical Journal Letters Pub Date : 2025-07-14 DOI:10.3847/2041-8213/ade99b

A. G. Cheriyan, S. Vig, Nirupam Roy, Samir Mandal, C. Carrasco-González, A. Rodríguez-Kamenetzky and A. Pasetto

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Abstract

Polarization measurements provide strong constraints on magnetic fields in star-forming systems. While magnetic field estimates of a few kG have been obtained near the surfaces of low-mass protostars, there are no analogous measurements in the immediate vicinity of the surface of massive protostars. We report the measurement of radio continuum circular polarization (CP) toward a massive protostar, IRAS 18162–2048, for the first time, using Karl G. Jansky Very Large Array observations. The fractional CP varies between 3% and 5% across the observed frequency range of 4–6 GHz. We consider multiple hypotheses for the production of CP and propose (i) gyrosynchrotron emission and (ii) Faraday conversion due to turbulence in the magnetic medium—both driven by mildly relativistic electrons as plausible mechanisms. We estimate, for the first time, a magnetic field B ≳ 20–35 G close to the massive protostar. The Lorentz factor of the low-energy electrons is estimated to be in the range γmin ∼ 5–7 for gyrosynchrotron emission and 80–100 for Faraday conversion from our observations. The magnetic field estimate can provide important constraints to the formation models of massive stars.

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首次探测到指向大质量原恒星的射电连续体中的圆偏振

偏振测量为恒星形成系统中的磁场提供了强有力的约束。虽然在低质量原恒星表面附近获得了几kG的磁场估计，但在大质量原恒星表面附近没有类似的测量结果。我们报告了首次使用卡尔·g·杨斯基甚大阵列观测对大质量原恒星IRAS 18162-2048的射电连续圆偏振（CP）测量。在观察到的4-6 GHz频率范围内，分数CP在3%到5%之间变化。我们考虑了产生CP的多种假设，并提出(i)回旋同步辐射和（ii）由于磁介质湍流引起的法拉第转换，两者都是由温和相对论性电子驱动的合理机制。我们首次估计，在这颗大质量原恒星附近，存在一个B > 20 - 35g的磁场。根据我们的观测，低能电子的洛伦兹因子估计在陀螺同步辐射的γmin ~ 5-7和法拉第转换的80-100范围内。磁场估计可以为大质量恒星的形成模型提供重要的约束。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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The Astrophysical Journal Letters

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