Hunting for interstellar molecules: rotational spectra of reactive species†

IF 3.3 3区化学 Q2 CHEMISTRY, PHYSICAL Faraday Discussions Pub Date : 2023-03-14 DOI:10.1039/D3FD00052D

Cristina Puzzarini, Silvia Alessandrini, Luca Bizzocchi and Mattia Melosso

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引用次数: 1

Abstract

Interstellar molecules are often highly reactive species, which are unstable under terrestrial conditions, such as radicals, ions and unsaturated carbon chains. Their detection in space is usually based on the astronomical observation of their rotational fingerprints. However, laboratory investigations have to face the issue of efficiently producing these molecules and preserving them during rotational spectroscopy measurements. A general approach for producing and investigating unstable/reactive species is presented by means of selected case-study molecules. The overall strategy starts from quantum-chemical calculations that aim at obtaining accurate predictions of the missing spectroscopic information required to guide spectral analysis and assignment. Rotational spectra of these species are then recorded by exploiting the approach mentioned above, and their subsequent analysis leads to accurate spectroscopic parameters. These are then used for setting up accurate line catalogs for astronomical searches.

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寻找星际分子:反应物质的旋转光谱†

星际分子通常是高活性物质，在地球条件下是不稳定的，如自由基、离子和不饱和碳链。它们在太空中的探测通常是基于对它们旋转指纹的天文观测。然而，实验室研究必须面对有效地产生这些分子并在旋转光谱测量期间保存它们的问题。通过选定的案例研究分子，提出了一种生产和研究不稳定/反应性物质的一般方法。总体策略从量子化学计算开始，旨在获得准确预测缺失的光谱信息，以指导光谱分析和分配。然后利用上述方法记录这些物质的旋转光谱，并对其进行后续分析，得到准确的光谱参数。然后用这些数据为天文搜索建立精确的线路目录。

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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