A Radially Resolved Magnetic Field Threading the Disk of TW Hya

The Astrophysical Journal Letters Pub Date : 2025-09-11 DOI:10.3847/2041-8213/adff4d

Richard Teague, Boy Lankhaar, Sean M. Andrews, Chunhua Qi, Roger R. Fu, David J. Wilner, John B. Biersteker and Joan R. Najita

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Abstract

We present a new approach to detecting and characterizing a magnetic field in protoplanetary disks through the differential broadening of unpolarized molecular emission from CN. To demonstrate this technique, we apply it to new Atacama Large Millimeter/submillimeter Array observations of the full complement of hyperfine components from the N = 1–0 transition, achieving a spatial and spectral resolution of and 80 m s−1, respectively. By fitting a model that incorporates the velocity structure of the disk, the potential non-LTE excitation of the molecule, and the Zeeman effect, we recover a radially resolved magnetic field with a strength of ∼10 mG between 60 and 120 au. The morphology of the field is also inferred through azimuthal variations in the line broadening, revealing a predominantly poloidal field at 60 au, sharply transitioning to one within the disk plane outside of the gap at 82 au. The signal-to-noise ratio of the data meant that the planar component was unable to be decomposed into toroidal and radial components. Lower limits on the local gas density (n(H2) ≳ 108 cm−3) from the excitation analysis of the CN emission correspond to a lower limit between 0.1 and 0.01 for the plasma β.

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TW Hya盘面的径向分辨磁场

我们提出了一种通过CN的非极化分子发射的微分展宽来探测和表征原行星盘中磁场的新方法。为了证明这一技术，我们将其应用于新的阿塔卡马大型毫米/亚毫米阵列对N = 1 - 0跃迁的全补超精细分量的观测，分别获得了80 m s - 1和80 m s - 1的空间和光谱分辨率。通过拟合一个包含磁盘速度结构、分子潜在的非lte激发和塞曼效应的模型，我们在60和120 au之间恢复了强度为~ 10 mG的径向分辨磁场。通过线宽的方位角变化也可以推断出场的形态，在60 au处显示出一个主要的极向场，在82 au处急剧过渡到间隙外的圆盘平面内。数据的信噪比意味着平面分量无法分解为环面分量和径向分量。从CN发射的激发分析得到的局部气体密度（n(H2) > 108 cm−3）的下限对应于等离子体β的0.1 ~ 0.01之间的下限。

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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