BASF SE, Scientific Modelling - Quantum Chemistry, Group Research, Carl-Bosch-Straße 38, Ludwigshafen am Rhein67056, Germany.
International Isocyanate Institute Inc. (III), 333 Route 46 West, Suite. 206, Mountain Lakes, New Jersey07046, United States.
J Phys Chem A. 2022 Dec 22;126(50):9333-9352. doi: 10.1021/acs.jpca.2c06011. Epub 2022 Dec 8.
Isocyanates are highly relevant industrial intermediates for polyurethane production. In this work, we used quantum chemistry and transition state theory (TST) to investigate the gas-phase reaction of isocyanates with the OH radical, which is likely one of the most significant chemical sinks for these compounds in the troposphere. -Tolyl-isocyanate (p-tolyl-NCO) was chosen as a proxy substance for the large-volume aromatic diisocyanate species toluene diisocyanate and methylene diphenyl diisocyanate. Besides p-tolyl-NCO + OH, the model reactions CHNCO + OH, HC═CHNCO + OH, CH-NCO + OH, CH-CH + OH, and CH + OH have been studied as well to analyze various substituent effects and to allow for comparison with literature. Quantum chemical computations at the CCSD(T)/cc-pV(T,Q → ∞)Z//M06-2X/def2-TZVP level were used as the basis for tunneling-corrected canonical TST calculations. For CHNCO + OH, H abstraction by OH at the methyl group is the main reaction channel according to our calculations and predicted to be four orders of magnitude faster than OH addition at the NCO group. The calculated rate coefficient (8.8 × 10 cm molecule s) at 298 K is in good agreement with experimental data from the literature. Likewise, for aromatic isocyanates, OH attack at the isocyanate group was found to be only a minor pathway compared to addition to the aromatic ring. In the OH + p-tolyl-NCO reaction, OH addition at the -position relative to the NCO group has been identified as the main initial reaction channel (branching fraction: 53.2%), with smaller but significant branching fractions for the H abstraction at the methyl group (9.6%) as well as the other ring addition reactions (ipso: 2.3%, meta: 24.5%, para: 10.5%, all relative to the NCO group). By comparing OH addition to the aromatic ring in p-tolyl-NCO with the respective ring addition reactions of phenyl isocyanate and toluene, the site-selective reactivity trends observed for ring addition in the OH + p-tolyl-NCO could be rationalized by a dominating positive mesomeric effect of the NCO group and a positive electron-donating (inductive) effect of the CH group. Except for the OH ring adduct formed from OH addition in ipso-position to the NCO group, we estimate the first-generation radical intermediates in the OH + p-tolyl-NCO reaction to have sufficiently long lifetimes to react with O under atmospheric conditions and undergo typical oxidative reaction cascades like those known for benzene or toluene.
异氰酸酯是生产聚氨酯的重要工业中间体。在这项工作中,我们使用量子化学和过渡态理论(TST)研究了异氰酸酯与 OH 自由基的气相反应,这可能是这些化合物在对流层中最重要的化学消耗途径之一。我们选择甲苯基异氰酸酯(p-甲苯基-NCO)作为大体积芳香二异氰酸酯甲苯二异氰酸酯和亚甲基二苯基二异氰酸酯的代表物质。除了 p-甲苯基-NCO + OH,我们还研究了模型反应 CHNCO + OH、HC=CHNCO + OH、CH-NCO + OH、CH-CH + OH 和 CH + OH,以分析各种取代基效应,并与文献进行比较。我们使用在 CCSD(T)/cc-pV(T,Q → ∞)Z//M06-2X/def2-TZVP 水平上进行的量子化学计算作为对隧道校正正则 TST 计算的基础。根据我们的计算,对于 CHNCO + OH,OH 在甲基上的 H 提取是主要反应通道,预计比 NCO 基团上的 OH 添加快四个数量级。在 298 K 下计算得到的速率系数(8.8×10cm 分子 s)与文献中的实验数据非常吻合。同样,对于芳香族异氰酸酯,与芳环加成相比,OH 攻击异氰酸酯基团只是一个次要途径。在 OH + p-甲苯基-NCO 反应中,已经确定相对于 NCO 基团的 -位置上的 OH 添加是主要的初始反应通道(分支分数:53.2%),甲基上的 H 提取(9.6%)以及其他环加成反应(ipso:2.3%、meta:24.5%、para:10.5%,均相对于 NCO 基团)的分支分数较小但也很显著。通过比较 OH 对 p-甲苯基-NCO 芳环的加成与苯基异氰酸酯和甲苯的相应环加成反应,我们可以通过 NCO 基团的主导正离域效应和 CH 基团的正给电子(诱导)效应来解释 OH + p-甲苯基-NCO 中环加成的选择性反应趋势。除了在 NCO 基团的 ipso 位置上由 OH 添加形成的 OH 环加合物外,我们估计 OH + p-甲苯基-NCO 反应中的第一代自由基中间体具有足够长的寿命,可在大气条件下与 O 反应,并经历典型的氧化反应级联,如已知的苯或甲苯。
