Using Surface Science Techniques to Investigate the Interaction of Acetonitrile with Dust Grain Analogue Surfaces

IF 1.7 4区 化学 Q4 CHEMISTRY, PHYSICAL Johnson Matthey Technology Review Pub Date : 2021-07-15 DOI:10.1595/205651321x16264409352535
Emily R. Ingman, Amber Shepherd, W. A. Brown
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引用次数: 1

Abstract

Surface science methodologies, such as reflection-absorption infrared spectroscopy (RAIRS) and temperature programmed desorption (TPD), are ideally suited to studying the interaction of molecules with model astrophysical surfaces. Here we describe the use of RAIRS and TPD to investigate the adsorption, interactions and thermal processing of acetonitrile and water containing model ices grown under astrophysical conditions on a graphitic dust grain analogue surface. Experiments show that acetonitrile physisorbs on the graphitic surface at all exposures. At the lowest coverages, repulsions between the molecules lead to a decreasing desorption energy with increasing coverage. Analysis of TPD data gives monolayer desorption energies ranging from 28.8 - 39.2 kJ mol-1 and an average multilayer desorption energy of 43.8 kJ mol-1. When acetonitrile is adsorbed in the presence of water ice, the desorption energy of monolayer acetonitrile shows evidence of desorption with a wide range of energies. An estimate of the desorption energy of acetonitrile from CI shows that it is increased to ~37 kJ mol-1 at the lowest exposures of acetonitrile. Amorphous water ice also traps acetonitrile on the graphite surface past its natural desorption temperature, leading to volcano and co-desorption. RAIRS data show that the C≡N vibration shifts, indicative of an interaction between the acetonitrile and the water ice surface.
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利用表面科学技术研究乙腈与尘粒相似表面的相互作用
表面科学方法,如反射吸收红外光谱(RAIRS)和程序升温脱附(TPD),非常适合研究分子与模型天体物理表面的相互作用。在这里,我们描述了使用RAIRS和TPD来研究在天体物理条件下在石墨尘粒模拟表面上生长的乙腈和含水模型冰的吸附、相互作用和热处理。实验表明,乙腈在所有暴露条件下都会在石墨表面发生物理吸附。在最低覆盖率下,分子之间的排斥导致解吸能随着覆盖率的增加而降低。TPD数据的分析给出了28.8-39.2kJ mol-1的单层解吸能和43.8kJ mol-1平均多层解吸能。当乙腈在水冰存在下吸附时,单层乙腈的解吸能显示出宽范围的解吸能。对乙腈从CI中的解吸能的估计表明,在乙腈的最低暴露量下,它增加到~37kJ mol-1。无定形水冰还将乙腈捕获在石墨表面,超过其自然解吸温度,导致火山和共解吸。RAIRS数据显示,C lect N振动发生了位移,表明乙腈和水冰表面之间存在相互作用。
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来源期刊
Johnson Matthey Technology Review
Johnson Matthey Technology Review CHEMISTRY, PHYSICAL-
CiteScore
4.30
自引率
4.30%
发文量
48
审稿时长
12 weeks
期刊介绍: Johnson Matthey Technology Review publishes articles, reviews and short reports on science enabling cleaner air, good health and efficient use of natural resources. Areas of application and fundamental science will be considered in the fields of:Advanced materials[...]Catalysis[...][...]Characterisation[...]Electrochemistry[...]Emissions control[...]Fine and speciality chemicals[...]Historical[...]Industrial processes[...]Materials and metallurgy[...]Modelling[...]PGM and specialist metallurgy[...]Pharmaceutical and medical science[...]Surface chemistry and coatings[...]Sustainable technologies.
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