50年的技术发展如何改变了毫米-太赫兹天文光谱学

P. Goldsmith
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引用次数: 3

摘要

大约50年前,毫米波天文光谱学开始探测星际空间中的一氧化碳。对银河系中大量分子物质云的探测回答了一个长期存在的问题,即恒星是由什么形成的,但要了解这些云的形成、结构和演化,需要在毫米/亚毫米/太赫兹范围内工作的更灵敏的接收器。测量恒星形成区域的运动需要分数频率分辨率R>3x105,结果外差系统已成为详细运动学研究的主导技术。为了揭示分子云中化学的复杂性,需要更高的灵敏度。为了实现这一目标,最初用作非线性元件的肖特基二极管首先被冷却以降低噪声,但随后被超导体绝缘体(SIS)和热电子测热计(HEB)混频器所取代。噪声温度从几千K降至100 K以下。本振从真空管发展到固态器件。大量的努力致力于开发频率乘法器,允许高达几个太赫兹的混频器工作,从频谱纯净,100 GHz以下的可调谐源开始。这使得无偏“光谱扫描”和更好地利用观测时间成为可能。量子级联激光LO允许开发频率达到5太赫兹甚至更高。单天线的收集面积增加了一个数量级以上。干涉测量阵列提供了前所未有的角度分辨率,可以详细观察从行星形成盘到遥远星系中恒星形成区域的各种来源。技术和天文光谱学之间的相互作用已经产生了巨大的成果,并且还在继续,为地面和空间应用开发了用于单个像素的新型混合器和复杂的焦平面阵列。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
How 50 Years of Technology Development Has Transformed Millimeter-THz Astronomical Spectroscopy
Millimeter wavelength astronomical spectroscopy started about 50 years ago, with the detection of carbon monoxide in interstellar space. The detection of massive clouds of molecular material in the Milky Way answered a long-standing question of from what stars form, but understanding the formation, structure, and evolution of these clouds demanded ever more sensitive receivers operating throughout the millimeter/submillimeter//THz range. Fractional frequency resolution R>3x105 is required to measure the motions in star-forming regions, with the result that heterodyne systems have become the dominant technology for detailed kinematic studies. To unravel the complexity of chemistry in molecular clouds, higher sensitivity was required. To achieve this, the Schottky diodes initially used as nonlinear elements were first cooled to reduce noise, but then replaced by superconductor insulator superconductor (SIS) and hot electron bolometer (HEB) mixers. Noise temperatures dropped from many thousands of K to < 100 K. Local oscillators (LOs) evolved from vacuum tubes to solid state devices. Large efforts were devoted to the development of frequency multipliers which allow mixers up to several THz to operate, starting with spectrally pure, tunable sources below 100 GHz. These allowed unbiased "spectral scans" and better use of observing time. The quantum cascade laser LO has allowed exploiting frequencies to 5 THz and beyond. Single antennas grew by more than an order of magnitude in collecting area. Interferometric arrays providing unprecedented angular resolution have allowed detailed observations of sources ranging from planet-forming disks to star-forming regions in distant galaxies. The interplay between technology and astronomical spectroscopy has been hugely productive, and continues, with new types of mixers for individual pixels and sophisticated focal plane arrays being developed for ground and space-based applications.
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