Para‐ortho hydrogen conversion: Solving a 90‐year old mystery

IF 2.6 Q2 MULTIDISCIPLINARY SCIENCES

Natural sciences (Weinheim, Germany) Pub Date : 2020-11-22 DOI:10.1002/NTLS.10002

Xia Zhang, T. Karman, G. Groenenboom, A. van der Avoird

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引用次数: 6

Abstract

Funding information ChinaScholarshipCouncil,NationalNatural ScienceFoundationofChina,Grant/Award Number: 11604118;ChinaPostdoctoral ScienceFoundation,Grant/AwardNumber: 2015M581390 Abstract Almost ninety years have passed since the experiments of Farkas and Sachsse [Z. Phys. Chem. B 1933; 23:1] on para-ortho hydrogen conversion catalyzed by paramagnetic species such as O2, but a detailed and quantitative understanding of the conversion process and its temperature dependencewas still lacking. Here, we present a complete and quantitative theoretical treatment of this catalytic process. Both interactions causing the conversion are included: the magnetic dipole-dipole coupling between the electron spin of O2 and the nuclear spins in H2 and the Fermi contact coupling from spin densities at the H-nuclei induced by O2. The latter were extracted from ab initio electronic structure calculations. State-to-state conversion cross sections and rate coefficients are obtained from quantummechanical coupled-channel calculations including the full anisotropic O2-H2 interaction potential and by treating both the spin-dependent couplings perturbatively. The total rate coefficient agrees with the experimental value recently measured by Wagner [Magn. Reson. Mater. Phys., Biol. Med. 2014; 27:195] in O2-H2 gas mixtures and explains the temperature dependence observed in the 1933measurements mentioned above.

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对位-正位氢转化:解决一个90年的谜团

中国博士后科学基金，资助/奖励号:2015M581390摘要Farkas和Sachsse的实验已经过去了近90年。理论物理。化学。B 1933;[23:1]对顺磁性物质如O2催化的对邻位氢转化进行了研究，但对其转化过程及其温度依赖性的详细和定量的了解仍然缺乏。在这里，我们提出了一个完整的和定量的理论处理这一催化过程。引起转换的两种相互作用包括:O2的电子自旋与H2中的核自旋之间的磁偶极子-偶极子耦合以及O2诱导的h核自旋密度的费米接触耦合。后者是从从头开始的电子结构计算中提取的。状态到状态转换截面和速率系数是通过量子力学耦合通道计算得到的，包括O2-H2全各向异性相互作用势，并通过对自旋相关耦合进行扰动处理。总速率系数与Wagner [Magn]最近测量的实验值一致。的原因。板牙。理论物理。、生物。医学。2014;[27:195]在O2-H2气体混合物中，并解释了在上面提到的1933年测量中观察到的温度依赖性。

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Natural sciences (Weinheim, Germany)

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