Structural and spectral properties of astronomical complex organic molecules: 1:1:1 glycine-X-Y and Y-glycine-X

Q2 Physics and Astronomy

Molecular Astrophysics Pub Date : 2020-12-01 DOI:10.1016/j.molap.2020.100086

Anita Kabi, Pradipta K. Behera, Prabhat K. Sahu

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引用次数: 0

Abstract

Current research to understand astrochemistry and astrobiology with regard to the weakly bound astronomical complexes including amino acids in the Inter-Stellar Medium (ISM), comets and meteorites at molecular level are flourishing and many new findings are emerging rapidly. Modern experimental techniques and computational investigations assisted by quantum chemical analysis are playing key role towards exploring the evolution of many molecular complexes in astrochemical environment and planetary atmospheres by affecting their stability as well as their structural and spectral properties. The present work deals with weekly bound complexes of glycine with small molecules like water, ammonia and HF as 1:1:1 Glycine-X-Y and Y-Glycine-X. The affects that influence the complexation, mainly involve through non-covalent interactions with these small molecules have been explored, based on various properties of the red shifted hydrogen bonds of the type: OHO, NHO, FHO, OHN and carbon-cantered blue shifted hydrogen bonds, CHO type, for all the stable complexes of 1:1:1 Glycine-X-Y and Y-Glycine-X with respect to their structural properties and spectral characterization. The computed Ray's asymmetry parameter, κ values for the investigated 1:1:1 Glycine-X-Y and Y-Glycine-X complexes are found to be negative and predicted as prolate-type asymmetric rotor. The computed rotational constants and IR spectra of these different complexes may assist in the interpretation and analysis of observational data and the data obtained in laboratory experiments. The possibilities of formation of such molecular complexes in the interstellar space may provide a direction to explore new possibilities.

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天文复杂有机分子的结构和光谱性质:1:1:1甘氨酸- x - y和y -甘氨酸- x

目前，从分子水平对星际介质(inter - star Medium, ISM)中的氨基酸、彗星和陨石等弱结合天文复合物的天体化学和天体生物学的研究正在蓬勃发展，许多新发现正在迅速涌现。在量子化学分析的辅助下，现代实验技术和计算研究对探索天体化学环境和行星大气中许多分子复合物的演化起着关键作用，通过影响它们的稳定性以及它们的结构和光谱特性。目前的工作涉及甘氨酸与水、氨和HF等小分子的每周结合配合物为1:1:1的甘氨酸- x - y和y -甘氨酸- x。通过对所有1:1:1甘氨酸- x - y和y -甘氨酸- x稳定配合物的结构性质和光谱表征，研究了红移氢键OHO型、NHO型、FHO型、OHN型和碳中心蓝移氢键CHO型的各种性质，主要是通过与这些小分子的非共价相互作用来影响配位的影响。所研究的1:1:1甘氨酸- x - y和y -甘氨酸- x配合物的计算Ray's不对称参数κ值为负，预测为长形不对称转子。计算出的这些不同配合物的旋转常数和红外光谱可以帮助解释和分析观测数据和实验室实验中获得的数据。这种分子复合物在星际空间形成的可能性为探索新的可能性提供了一个方向。

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来源期刊

Molecular Astrophysics ASTRONOMY & ASTROPHYSICS-

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期刊介绍： Molecular Astrophysics is a peer-reviewed journal containing full research articles, selected review articles, and thematic issues. Molecular Astrophysics is a new journal where researchers working in planetary and exoplanetary science, astrochemistry, astrobiology, spectroscopy, physical chemistry and chemical physics can meet and exchange their ideas. Understanding the origin and evolution of interstellar and circumstellar molecules is key to understanding the Universe around us and our place in it and has become a fundamental goal of modern astrophysics. Molecular Astrophysics aims to provide a platform for scientists studying the chemical processes that form and dissociate molecules, and control chemical abundances in the universe, particularly in Solar System objects including planets, moons, and comets, in the atmospheres of exoplanets, as well as in regions of star and planet formation in the interstellar medium of galaxies. Observational studies of the molecular universe are driven by a range of new space missions and large-scale scale observatories opening up. With the Spitzer Space Telescope, the Herschel Space Observatory, the Atacama Large Millimeter/submillimeter Array (ALMA), NASA''s Kepler mission, the Rosetta mission, and more major future facilities such as NASA''s James Webb Space Telescope and various missions to Mars, the journal taps into the expected new insights and the need to bring the various communities together on one platform. The journal aims to cover observational, laboratory as well as computational results in the galactic, extragalactic and intergalactic areas of our universe.