Experimental and Theoretical Investigation of the Reaction of C2H with Formaldehyde (CH2O) at Very Low Temperatures and Application to Astrochemical Models

IF 2.9 3区化学 Q2 CHEMISTRY, MULTIDISCIPLINARY

ACS Earth and Space Chemistry Pub Date : 2024-11-20 DOI:10.1021/acsearthspacechem.4c0018810.1021/acsearthspacechem.4c00188

Kevin M. Douglas*, Niclas A. West, Daniel I. Lucas, Marie Van de Sande, Mark A. Blitz and Dwayne E. Heard*,

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引用次数: 0

Abstract

Rate coefficients for the reaction of C₂H with CH₂O were measured for the first time over the temperature range of 37–603 K, with the C₂H radicals produced by pulsed laser photolysis and detected by CH radical chemiluminescence following their reaction with O₂. The low temperature measurements (≤93 K) relevant to the interstellar medium were made within a Laval nozzle gas expansion, while higher temperature measurements (≥308 K) were made within a temperature controlled reaction cell. The rate coefficients display a negative temperature dependence below 300 K, reaching (1.3 ± 0.2) × 10^–10 cm³ molecule^–1 s^–1 at 37 K, while only a slight positive temperature dependence is observed at higher temperatures above 300 K. Ab initio calculations of the potential energy surface (PES) were combined with rate theory calculations using the MESMER master-equation program in order to predict rate coefficients and branching ratios. The three lowest energy entrance channels on the PES all proceed via the initial formation of a weakly bound prereaction complex, bound by ∼5 kJ mol^–1, followed by either a submerged barrier on the route to the H-abstraction products (C₂H₂ + CHO), or emerged barriers on the routes to the C- or O-addition species. MESMER calculations indicated that over the temperature range investigated (10–600 K) the two addition channels were uncompetitive, accounting for less 0.3% of the total product yield even at 600 K. The PES containing only the H-abstraction product channel was fit to the experimentally determined rate coefficients, with only a minor adjustment to the height of the submerged barrier (from −2.6 to −5.9 kJ mol^–1) required. Using this new submerged barrier height, and including the subsequent dissociation of the CHO product into CO + H in the PES, rate coefficients and branching ratios were calculated over a wide range of temperatures and pressures and these used to recommend best-fit modified Arrhenius expressions for use in astrochemical modeling. Inclusion of the new rate coefficients and branching ratios in a UMIST chemical model of an outflow from an asymptotic giant branch (AGB) star yielded no significant changes in the abundances of the reactants or the products of the reaction, however, removal of the C-addition channel currently in the UMIST Rate22 database did result in a significant reduction in the abundance of propynal (HCCCHO).

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C2H与甲醛（CH2O）在极低温下反应的实验与理论研究及其在天体化学模型中的应用

在37 ~ 603 K的温度范围内，首次测定了C2H与CH2O反应的速率系数，其中C2H自由基由脉冲激光光解产生，与O2反应后用CH自由基化学发光法检测。与星际介质相关的低温测量（≤93 K）在拉瓦尔喷嘴气体膨胀中进行，而较高的温度测量（≥308 K）在温度控制的反应池中进行。速率系数在300 K以下表现为负温度依赖关系，在37 K时达到（1.3±0.2）× 10-10 cm3分子- 1 s-1，而在300 K以上的高温下仅观察到轻微的正温度依赖关系。利用MESMER主方程程序将势能面（PES）的从头计算与速率理论计算相结合，以预测速率系数和分支比。PES上的三个最低能量入口通道都是通过初始形成一个弱结合的预反应复合物，结合量为~ 5 kJ mol-1，然后在通往h萃取产物（C2H2 + CHO）的路上有一个淹没的势垒，或者在通往C或o加成物质的路上有一个出现的势垒。MESMER计算表明，在所研究的温度范围内（10-600 K），两个添加通道不具有竞争性，即使在600 K时也只占总产品收率的不到0.3%。只包含h萃取产物通道的PES符合实验确定的速率系数，只需要对淹没势垒的高度进行微小的调整（从−2.6到−5.9 kJ mol-1）。利用这一新的淹没势垒高度，并包括CHO产物在PES中随后解离成CO + H的过程，计算了在很宽的温度和压力范围内的速率系数和分支比，这些系数和分支比用于推荐最适合用于天体化学建模的修正阿伦尼乌斯表达式。在UMIST的渐近巨支（AGB）星流出物的化学模型中加入新的速率系数和分支比，并没有对反应物或反应产物的丰度产生显著的变化，然而，去除UMIST Rate22数据库中目前的c -加成通道确实导致丙基（HCCCHO）丰度的显著降低。

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来源期刊

ACS Earth and Space Chemistry Earth and Planetary Sciences-Geochemistry and Petrology

CiteScore

5.30

自引率

11.80%

发文量

249

期刊介绍： The scope of ACS Earth and Space Chemistry includes the application of analytical, experimental and theoretical chemistry to investigate research questions relevant to the Earth and Space. The journal encompasses the highly interdisciplinary nature of research in this area, while emphasizing chemistry and chemical research tools as the unifying theme. The journal publishes broadly in the domains of high- and low-temperature geochemistry, atmospheric chemistry, marine chemistry, planetary chemistry, astrochemistry, and analytical geochemistry. ACS Earth and Space Chemistry publishes Articles, Letters, Reviews, and Features to provide flexible formats to readily communicate all aspects of research in these fields.