Atacama Large Aperture Submillimeter Telescope (AtLAST) science: Our Galaxy.

Open research Europe Pub Date : 2024-06-05 eCollection Date: 2024-01-01 DOI:10.12688/openreseurope.17450.1
Pamela Klaassen, Alessio Traficante, Maria Beltrán, Kate Pattle, Mark Booth, Joshua Lovell, Jonathan Marshall, Alvaro Hacar, Brandt Gaches, Caroline Bot, Nicolas Peretto, Thomas Stanke, Doris Arzoumanian, Ana Duarte Cabral, Gaspard Duchêne, David Eden, Antonio Hales, Jens Kauffmann, Patricia Luppe, Sebastian Marino, Elena Redaelli, Andrew Rigby, Álvaro Sánchez-Monge, Eugenio Schisano, Dmitry Semenov, Silvia Spezzano, Mark Thompson, Friedrich Wyrowski, Claudia Cicone, Tony Mroczkowski, Martin Cordiner, Luca Di Mascolo, Doug Johnstone, Eelco van Kampen, Minju Lee, Daizhong Liu, Thomas Maccarone, Amélie Saintonge, Matthew Smith, Alexander Thelen, Sven Wedemeyer
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Abstract

As we learn more about the multi-scale interstellar medium (ISM) of our Galaxy, we develop a greater understanding for the complex relationships between the large-scale diffuse gas and dust in Giant Molecular Clouds (GMCs), how it moves, how it is affected by the nearby massive stars, and which portions of those GMCs eventually collapse into star forming regions. The complex interactions of those gas, dust and stellar populations form what has come to be known as the ecology of our Galaxy. Because we are deeply embedded in the plane of our Galaxy, it takes up a significant fraction of the sky, with complex dust lanes scattered throughout the optically recognizable bands of the Milky Way. These bands become bright at (sub-)millimetre wavelengths, where we can study dust thermal emission and the chemical and kinematic signatures of the gas. To properly study such large-scale environments, requires deep, large area surveys that are not possible with current facilities. Moreover, where stars form, so too do planetary systems, growing from the dust and gas in circumstellar discs, to planets and planetesimal belts. Understanding the evolution of these belts requires deep imaging capable of studying belts around young stellar objects to Kuiper belt analogues around the nearest stars. Here we present a plan for observing the Galactic Plane and circumstellar environments to quantify the physical structure, the magnetic fields, the dynamics, chemistry, star formation, and planetary system evolution of the galaxy in which we live with AtLAST; a concept for a new, 50m single-dish sub-mm telescope with a large field of view which is the only type of facility that will allow us to observe our Galaxy deeply and widely enough to make a leap forward in our understanding of our local ecology.

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阿塔卡马大孔径亚毫米波望远镜(ATLAST)科学:我们的银河系
随着我们对银河系多尺度星际介质(ISM)了解的增多,我们对巨分子云(GMC)中大尺度弥漫气体和尘埃之间的复杂关系、它们如何运动、如何受到附近大质量恒星的影响以及这些巨分子云中的哪些部分最终坍缩为恒星形成区有了更深入的了解。这些气体、尘埃和恒星群之间复杂的相互作用形成了我们银河系的生态。由于我们深深地嵌入了银河系的平面,它占据了天空的很大一部分,复杂的尘埃通道散布在整个银河系的光学可识别带中。这些波段在(亚)毫米波长下变得明亮,我们可以在这里研究尘埃的热辐射以及气体的化学和运动特征。要正确研究这样的大尺度环境,需要进行深层次、大面积的巡天观测,而目前的设备无法做到这一点。此外,恒星形成的地方也会形成行星系统,从星盘周围的尘埃和气体发展到行星和行星带。要了解这些星带的演变过程,就需要对年轻恒星天体周围的星带以及最近恒星周围的柯伊伯带类似物进行深度成像研究。在这里,我们提出了一个利用 AtLAST 观测银河系平面和星环环境的计划,以量化我们所生活的银河系的物理结构、磁场、动力学、化学、恒星形成和行星系统演化;这是一个新的 50 米单碟亚微米大视场望远镜的概念,它是唯一一种能够让我们深入而广泛地观测银河系的设施,足以使我们对本地生态的认识向前迈进一大步。
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