与天体物理环境有关的含 H2O、N2、NH3、CO2 和 C2H3N 的热加工冰的实验室模拟物

Current Physics Pub Date : 2024-01-25 DOI:10.2174/0127723348285603231228110017

Douglas White

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引用次数: 0

摘要

实验室模拟有助于对外太空冰体的地面和天基观测。众所周知，NH3 和 CO2 可以相互作用，形成氨基甲酸铵（CH6N2O2）。众所周知，NH3 和 CO2 可以相互作用形成氨基甲酸铵（CH6N2O2）。本研究在实验室中通过中红外吸收光谱法研究了热处理富含 H2O 的冰中的 NH3 和 CO2。特别是，在系统实验中，在 150 K 下热退火超过四小时的 NH3 冰混合物中出现了二氧化碳，这表明氨基甲酸铵有可能捕获冰基质中的挥发物。特别是，在系统实验中，NH3-冰混合物在 150 K 下热退火四个多小时后出现了二氧化碳，这表明氨基甲酸铵有可能捕获冰基质中的挥发性物质。此外，还对含有 H2O、CO2 和 NH3 的冰混合物中的乙腈（C2H3N）进行了研究。当温度缓慢升高（≤ 5K/分钟）和退火温度高达150 K时，记录了吸收峰位置的变化。

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Laboratory Analogs of Thermally Processed Ices Containing H2O, N2, NH3, CO2, and C2H3N Relevant to Astrophysical Environments

Laboratory simulations can benefit ground- and space-based observations of icy bodies in outer space. It is well-known that NH3 and CO2 can interact, forming ammonium carbamate (CH6N2O2). Laboratory simulations can benefit ground- and space-based observations of icy bodies in outer space. It is well-known that NH3 and CO2 can interact forming ammonium carbamate (CH6N2O2). This study examines NH3 and CO2 in thermally processed H2O-rich ices in the laboratory via mid-infrared absorption spectroscopy. In particular, the presence of CO2 in NH3- ice mixtures thermally annealed at 150 K for more than four hours in systematic experiments suggested that ammonium carbamate could potentially trap volatiles within the ice matrix. This study examines NH3 and CO2 in thermally processed H2O-rich ices in the laboratory via mid-infrared absorption spectroscopy. In particular, the presence of CO2 in NH3-ice mixtures thermally annealed at 150 K for more than four hours in systematic experiments suggested that ammonium carbamate could potentially trap volatiles within the ice matrix. Additional studies with acetonitrile (C2H3N) in ice mixtures containing H2O, CO2, and NH3 were also performed. Additional studies with acetonitrile (C2H3N) in ice mixtures containing H2O, CO2, and NH3 were also performed. Absorption peak position changes were recorded when the temperature was slowly increased (≤ 5K/min) and also annealed at temperatures up to 150 K. These studies will hopefully be useful in interpreting pre-biotic chemistry in the Solar System.

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Current Physics

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