Gas-phase solvation of NO2− and NO3− by ethyl nitrate

International Journal of Mass Spectrometry and Ion Physics Pub Date : 1983-09-01 DOI:10.1016/0020-7381(83)85036-0

S. Włodek, Z. Łuczyński, H. Wincel

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引用次数: 3

Abstract

The gas-phase clustering reactions NO₂⁻· (C₂H₅ONO₂)_n−1 + C₂H₅ONO₂ = NO₂⁻· (C₂H₅ONO₂)n (n = 1–3) NO₃⁻· (C₂H₅ONO₂)_n−1 + C₂H₅ONO₂ = NO₃⁻· (C₂H₅ONO₂)n (n = 1 and 2) have been studied by means of a high-pressure mass spectrometer at temperatures from 200 to 380 K and at total pressures of 0.5–2 torr. It is demonstrated that under the conditions used here these reactions, with the exception of NO₂⁻ + C₂H₅ONO₂ = NO₂⁻· C₂H₅ONO₂, achieve thermodynamic equilibrium above 1 torr. On the basis of the temperature dependence measurements of the equilibrium constants, thermodynamic data have been determined. The following ΔH_n−1⁰,_n values were obtained: NO₂⁻·(C₂H₅ONO₂)_n; ΔH_0,1⁰ =−20.9 (indirectly obtained), ΔH_1,2⁰ = −8.5 and ΔH_2,3⁰ = −7.3 kcal mol⁻¹; NO₂⁻·(C₂H₅ONO₂)_n; ΔH_0,1⁰ = −17.2 and ΔH_1,2⁰ = −7.2 kcal mol⁻¹.

Semiempirical INDO MO calculations were performed for NO₂⁻· (C₂H₅0NO₂)_n = _1,2 and NO₃⁻·(C₂H₅ONO₂)_n = _1,2 to test the structures and binding energies of these systems. The experimental observations are discussed in terms of the structure stabilities of the solvated ions.

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硝酸乙酯气相溶剂化NO2 -和NO3 -

用高压质谱仪研究了在温度200 ~ 380 K、总压力0.5 ~ 2 torr条件下，NO2−·(C2H5ONO2)n−1 + C2H5ONO2 = NO2−·(C2H5ONO2)n (n = 1 ~ 3) + C2H5ONO2 = NO3−·(C2H5ONO2)n (n = 1 ~ 2)气相聚簇反应。结果表明，在本实验条件下，除NO2−+ C2H5ONO2 = NO2−·C2H5ONO2外，其余反应均在1 torr以上达到热力学平衡。根据平衡常数的温度依赖性测量，确定了热力学数据。得到ΔHn−10,n值:NO2−·(C2H5ONO2)n;ΔH0,10 =−20.9(间接得到)，ΔH1,20 =−8.5和ΔH2,30 =−7.3千卡摩尔−1;NO2−·(C2H5ONO2) n;ΔH0,10 =−17.2和ΔH1,20 =−7.2 kcal mol−1。对NO2−·(C2H50NO2)n = 1,2和NO3−·(C2H5ONO2)n = 1,2进行了半经验INDO MO计算，测试了这些体系的结构和结合能。从溶剂化离子结构稳定性的角度对实验结果进行了讨论。

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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International Journal of Mass Spectrometry and Ion Physics

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Editorial Subject index Author index High resolution accurate mass measurements of FAB-generated ions by use of peak matching and multichannel analyzer techniques. Secondary ion mass spectrometry of low-temperature solids