嵌入各种分子环境中的固态 HCN 的红外光谱,与 JWST 获得的数据进行比较

Maksim Ozhiganov, Mikhail Medvedev, Varvara Karteyeva, Ruslan Nakibov, Uliana Sapunova, Vadim Krushinsky, Ksenia Stepanova, Anastasia Tryastsina, Aleksandr Gorkovenko, Gleb Fedoseev and Anton Vasyunin
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摘要

氰化氢(HCN)分子是恒星和行星形成区域氮元素化学演变的重要示踪剂。这主要是因为 N 原子和 N2 分子在射电和红外(IR)范围内很难被观测到。反过来,在恒星形成的各个阶段都可以观测到气相 HCN,包括年轻恒星周围的星盘、彗星彗尾和行星卫星的大气层。尽管气相观测的地理范围很大,但仍缺乏对星际 HCN 冰的识别。在这项工作中,我们介绍了在新型超高真空低温仪器上进行的一系列红外光谱测量,目的是促进对星际 HCN 冰的搜索。我们获得了一系列在 10 K 温度下嵌入 H2O、H2O:NH3、CO、CO2 和 CH3OH 冰的 HCN 分子的高分辨率实验室红外光谱。这些星际冰模拟物旨在模拟星际晶粒表面冰幔的主要成分包围 HCN 分子的情况。此外,还获得了嵌入固体 C6H6、C5H5N 和 C6H5NH2 中的 HCN 分子的光谱,以某种方式模拟 HCN 分子与富含多环芳烃的星际晶粒碳质材料之间的相互作用。获得的实验室光谱数据与 IceAge 团队公开的 NIRSpec 詹姆斯-韦伯太空望远镜对静态分子云的观测结果进行了比较。
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Infrared Spectra of Solid HCN Embedded in Various Molecular Environments for Comparison with the Data Obtained with JWST
Hydrogen cyanide (HCN) molecules serve as an important tracer for the chemical evolution of elemental nitrogen in the regions of star and planet formation. This is largely explained by the fact that N atoms and N2 molecules are poorly accessible for observation in the radio and infrared (IR) ranges. In turn, gas-phase HCN can be observed at various stages of star formation, including disks around young stars, cometary comas, and atmospheres of the planetary satellites. Despite the large geography of gas-phase observations, an identification of interstellar HCN ice is still lacking. In this work we present a series of IR spectroscopic measurements performed at the new ultrahigh vacuum cryogenic apparatus aiming to facilitate the search for interstellar HCN ice. A series of high-resolution laboratory IR spectra of HCN molecules embedded in the H2O, H2O:NH3, CO, CO2, and CH3OH ices at 10 K temperature is obtained. These interstellar ice analogues aim to simulate the surroundings of HCN molecules by the main constituents of the icy mantles on the surface of the interstellar grains. In addition, the spectra of HCN molecules embedded in the solid C6H6, C5H5N, and C6H5NH2 are obtained to somehow simulate the interaction of HCN molecules with carbonaceous material of the grains rich in polycyclic aromatic hydrocarbons. The acquired laboratory spectroscopic data are compared with the publicly available results of NIRSpec James Webb Space Telescope observations toward quiescent molecular clouds performed by the IceAge team.
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