exoALMA. I. Science Goals, Project Design, and Data Products

The Astrophysical Journal Letters Pub Date : 2025-04-27 DOI:10.3847/2041-8213/adc43b

Richard Teague, Myriam Benisty, Stefano Facchini, Misato Fukagawa, Christophe Pinte, Sean M. Andrews, Jaehan Bae, Marcelo Barraza-Alfaro, Gianni Cataldi, Nicolás Cuello, Pietro Curone, Ian Czekala, Daniele Fasano, Mario Flock, Maria Galloway-Sprietsma, Himanshi Garg, Cassandra Hall, Iain Hammond, Thomas Hilder, Jane Huang, John D. Ilee, Andrés F. Izquierdo, Kazuhiro Kanagawa, Geoffroy Lesur, Giuseppe Lodato, Cristiano Longarini, Ryan A. Loomis, Frédéric Masset, Francois Menard, Ryuta Orihara, Daniel J. Price, Giovanni Rosotti, Jochen Stadler, Leonardo Testi, Hsi-Wei Yen, Gaylor Wafflard-Fernandez, David J. Wilner, Andrew J. Winter, Lisa Wölfer, Tomohiro C. Yoshida and Brianna Zawadzki

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Abstract

Planet formation is a hugely dynamic process requiring the transport, concentration, and assimilation of gas and dust to form the first planetesimals and cores. With access to observations with extremely high spatial and spectral resolution at unprecedented sensitivities, it is now possible to probe the planet-forming environment in detail. To this end, the exoALMA Large Program targeted 15 large protoplanetary disks, ranging between ∼1″ and ∼7″ in radius, and mapped the gas and dust distributions. 12CO J = 3–2, 13CO J = 3–2, and CS J = 7–6 molecular emission was imaged at high angular ( ) and spectral (∼100 m s−1) resolution, achieving a surface brightness temperature sensitivity of ∼1.5 K over a single channel, while the 330 GHz continuum emission was imaged at 90 mas resolution and achieved a point source sensitivity of ∼40 μJy beam−1. These observations constitute some of the deepest observations of protoplanetary disks to date. Extensive substructure was found in all but one disk, traced by both dust continuum and molecular line emission. In addition, the molecular emission allowed for the velocity structure of the disks to be mapped with excellent precision (uncertainties of the order of 10 m s−1), revealing a variety of kinematic perturbations across all sources. From this sample it is clear that, when observed in detail, all disks appear to exhibit physical and dynamical substructure indicative of ongoing dynamical processing due to young, embedded planets, large-scale (magneto)hydrodynamical instabilities or winds.

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exoALMA。1、科学目标、项目设计与数据产品

行星的形成是一个巨大的动态过程，需要气体和尘埃的运输、集中和同化来形成第一批星子和核心。有了极高的空间和光谱分辨率和前所未有的灵敏度，现在有可能详细探测行星形成的环境。为此，exoALMA大型计划瞄准了半径在~ 1″和~ 7″之间的15个大型原行星盘，并绘制了气体和尘埃分布。12CO J = 3-2, 13CO J = 3-2和CS J = 7-6分子发射在高角（）和光谱（~ 100 m s−1）分辨率下成像，在单通道上获得了表面亮度温度灵敏度为~ 1.5 K，而330 GHz连续发射在90 mas分辨率下成像，获得了点光源灵敏度为~ 40 μJy beam−1。这些观测构成了迄今为止对原行星盘最深的观测。在除一个圆盘外的所有圆盘上都发现了广泛的亚结构，通过尘埃连续体和分子线发射进行了追踪。此外，分子发射使得磁盘的速度结构以极好的精度被映射（10 m s−1的不确定性），揭示了所有源的各种运动扰动。从这个样本中可以清楚地看到，当详细观察时，所有的圆盘似乎都表现出物理和动力的子结构，表明由于年轻的、嵌入的行星、大尺度（磁）流体动力不稳定性或风而正在进行的动力处理。

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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