Where You Protonate Matters: Deciphering the Unimolecular Chemistry of Protonated Myrcene and Linalool

IF 1.9 3区化学 Q3 BIOCHEMICAL RESEARCH METHODS

Journal of Mass Spectrometry Pub Date : 2024-10-01 DOI:10.1002/jms.5096

Edgar White Buenger, Paul M. Mayer

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Abstract

The unimolecular reactions of protonated myrcene and linalool were investigated by collision-induced dissociation and density functional theory calculations. Experiments on a triple quadrupole mass spectrometer showed that protonated myrcene undergoes two major unimolecular reactions losing propene and isobutene, and two minor reactions of ethene and propane loss. In each case, the product ion consists of a substituted five-member ring. Protonation of myrcene was found to form four distinct protomers, three of which can be significantly populated in the ion source. The observed fragmentation reactions were calculated and found to depend on the starting protomer. Each pathway consisted of several hydrogen-migration and ring-forming/opening steps on the way to the observed products. Likewise, protonation of linalool also produces three distinct protomers, with the global minimum being formed by protonation of a central double bond. The major reaction is water loss to form protonated myrcene, but two minor channels were also observed resulting in loss of acetone and isobutene. The calculated minimum energy reaction pathways were found to be consistent with the relative abundances of the ions in the experimental breakdown diagrams.

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质子化的位置很重要：解密质子化月桂烯和芳樟醇的单分子化学。

通过碰撞诱导解离和密度泛函理论计算，研究了质子化芳樟烯和芳樟醇的单分子反应。在三重四极质谱仪上进行的实验表明，质子化的月桂烯会发生失去丙烯和异丁烯的两个主要单分子反应，以及失去乙烯和丙烷的两个次要反应。在每种情况下，产物离子都由一个取代的五元环组成。研究发现，质子化月桂烯会形成四种不同的原生体，其中三种在离子源中的含量较高。对观察到的碎片反应进行了计算，发现其取决于起始原体。每种途径都包括几个氢迁移和成环/开环步骤，最终形成观察到的产物。同样，芳樟醇的质子化反应也会产生三种不同的原生质体，其中最小的原生质体是由一个中心双键质子化形成的。主要反应是失水，形成质子化的芳樟烯，但也观察到两个次要反应途径，导致丙酮和异丁烯的损失。计算得出的最小能量反应途径与实验分解图中离子的相对丰度一致。

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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来源期刊

Journal of Mass Spectrometry 化学-光谱学

CiteScore

5.10

自引率

0.00%

发文量

审稿时长

1.5 months

期刊介绍： The Journal of Mass Spectrometry publishes papers on a broad range of topics of interest to scientists working in both fundamental and applied areas involving the study of gaseous ions. The aim of JMS is to serve the scientific community with information provided and arranged to help senior investigators to better stay abreast of new discoveries and studies in their own field, to make them aware of events and developments in associated fields, and to provide students and newcomers the basic tools with which to learn fundamental and applied aspects of mass spectrometry.