P(4S) + NH(3Σ -)和N(4S) + PH(3Σ -)反应是星际氮化磷的来源

IF 4.5 3区物理与天体物理 Q1 ASTRONOMY & ASTROPHYSICS

Publications of the Astronomical Society of Australia Pub Date : 2023-03-07 DOI:10.1017/pasa.2023.13

A. C. R. Gomes, A. C. Souza, A. Jasper, B. R. Galvão

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引用次数: 1

摘要

氮化磷(PN)被认为是星际介质(ISM)中磷的主要储集层之一。因此，了解哪些反应在空间中产生PN并预测其速率系数对于模拟含磷物种的相对丰度和阐明磷在天体化学中的作用非常重要。在这项工作中，我们通过高精度从头计算和变反应坐标过渡态理论(VRC-TST)探索了$\textrm{P}(^4\textrm{S}) + \textrm{NH}(^3\Sigma^-)$和$\textrm{N}(^4\textrm{S}) + \textrm{PH}(^3\Sigma^-)$反应的势能面和$\textrm{H}(^2\textrm{S}) + \textrm{PN}(^1\Sigma^+)$的形成。我们发现两个反应都没有激活势垒，并且具有相似的速率系数，可以用改进的Arrhenius方程来描述($\textrm{P} + \textrm{NH} \longrightarrow \textrm{H} + \textrm{PN}$反应为$k(T)=\alpha\!\left( T/300 \right)^{\beta} \exp\!{(\!-\!\gamma/T)})$, $\alpha=0.93\times 10^{-10}\rm cm^3\,s^{-1}$, $\beta=-0.18$和$\gamma=0.24\, \rm K$, $\textrm{N} + \textrm{PH} \longrightarrow \textrm{H} + \textrm{PN}$反应为$\alpha=0.88\times 10^{-10}\rm cm^3\,s^{-1}$, $\beta=-0.18$和$\gamma=1.01\, \rm K$)。预计这两种反应都与模拟PN丰度有关，即使在ISM的寒冷环境中也是如此。考虑到空间中氢的丰度，我们还预测了通过H + PN碰撞破坏PN的速率系数。

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The P(4S) + NH(3Σ–) and N(4S) + PH(3Σ–)reactions as sources of interstellar phosphorus nitride

Abstract Phosphorus nitride (PN) is believed to be one of the major reservoirs of phosphorus in the interstellar medium (ISM). For this reason, understanding which reactions produce PN in space and predicting their rate coefficients is important for modelling the relative abundances of P-bearing species and clarifying the role of phosphorus in astrochemistry. In this work, we explore the potential energy surfaces of the $\textrm{P}(^4\textrm{S}) + \textrm{NH}(^3\Sigma^-)$ and $\textrm{N}(^4\textrm{S}) + \textrm{PH}(^3\Sigma^-)$ reactions and the formation of $\textrm{H}(^2\textrm{S}) + \textrm{PN}(^1\Sigma^+)$ through high accuracy ab initio calculations and the variable reaction coordinate transition state theory (VRC-TST). We found that both reactions proceed without an activation barrier and with similar rate coefficients that can be described by a modified Arrhenius equation ( $k(T)=\alpha\!\left( T/300 \right)^{\beta} \exp\!{(\!-\!\gamma/T)})$ with $\alpha=0.93\times 10^{-10}\rm cm^3\,s^{-1}$ , $\beta=-0.18$ and $\gamma=0.24\, \rm K$ for the $\textrm{P} + \textrm{NH} \longrightarrow \textrm{H} + \textrm{PN}$ reaction and $\alpha=0.88\times 10^{-10}\rm cm^3\,s^{-1}$ , $\beta=-0.18$ and $\gamma=1.01\, \rm K$ for the $\textrm{N} + \textrm{PH} \longrightarrow \textrm{H} + \textrm{PN}$ one. Both reactions are expected to be relevant for modelling PN abundances even in the cold environments of the ISM. Given the abundance of hydrogen in space, we have also predicted rate coefficients for the destruction of PN via H + PN collisions.

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来源期刊

Publications of the Astronomical Society of Australia 地学天文-天文与天体物理

CiteScore

5.90

自引率

9.50%

发文量

审稿时长

>12 weeks

期刊介绍： Publications of the Astronomical Society of Australia (PASA) publishes new and significant research in astronomy and astrophysics. PASA covers a wide range of topics within astronomy, including multi-wavelength observations, theoretical modelling, computational astronomy and visualisation. PASA also maintains its heritage of publishing results on southern hemisphere astronomy and on astronomy with Australian facilities. PASA publishes research papers, review papers and special series on topical issues, making use of expert international reviewers and an experienced Editorial Board. As an electronic-only journal, PASA publishes paper by paper, ensuring a rapid publication rate. There are no page charges. PASA''s Editorial Board approve a certain number of papers per year to be published Open Access without a publication fee.