Thomsen Ditte L, Nichols Charles M, Reece Jennifer N, Hammerum Steen, Bierbaum Veronica M
Department of Chemistry, University of Copenhagen, Universitetsparken 5, DK-2100, Copenhagen, Denmark.
J Am Soc Mass Spectrom. 2014 Feb;25(2):159-68. doi: 10.1007/s13361-013-0781-z. Epub 2013 Dec 18.
The enhanced reactivity of α-nucleophiles, which contain an electron lone pair adjacent to the reactive site, has been demonstrated in solution and in the gas phase and, recently, for the gas-phase S(N)2 reactions of the microsolvated HOO(-)(H2O) ion with methyl chloride. In the present work, we continue to explore the significance of microsolvation on the α-effect as we compare the gas-phase reactivity of the microsolvated α-nucleophile HOO(-)(H2O) with that of microsolvated normal alkoxy nucleophiles, RO(-)(H2O), in reactions with methyl formate, where three competing reactions are possible. The results reveal enhanced reactivity of HOO(-)(H2O) towards methyl formate, and clearly demonstrate the presence of an overall α-effect for the reactions of the microsolvated α-nucleophile. The association of the nucleophiles with a single water molecule significantly lowers the degree of proton abstraction and increases the S(N)2 and B(AC)2 reactivity compared with the unsolvated analogs. HOO(-)(H2O) reacts with methyl formate exclusively via the B(AC)2 channel. While microsolvation lowers the overall reaction efficiency, it enhances the B(AC)2 reaction efficiency for all anions compared with the unsolvated analogs. This may be explained by participation of the solvent water molecule in the B(AC)2 reaction in a way that continuously stabilizes the negative charge throughout the reaction.
α-亲核试剂(在反应位点附近含有孤对电子)的反应活性增强已在溶液和气相中得到证实,最近在微溶剂化的HOO⁻(H₂O)离子与氯甲烷的气相S(N)2反应中也得到了证实。在本工作中,我们继续探索微溶剂化对α-效应的重要性,比较了微溶剂化的α-亲核试剂HOO⁻(H₂O)与微溶剂化的正常烷氧基亲核试剂RO⁻(H₂O)在与甲酸甲酯反应中的气相反应活性,该反应中可能存在三种竞争反应。结果表明HOO⁻(H₂O)对甲酸甲酯的反应活性增强,清楚地证明了微溶剂化的α-亲核试剂反应中存在整体α-效应.与未溶剂化类似物相比,亲核试剂与单个水分子的缔合显著降低了质子夺取程度,并提高了S(N)2和B(AC)2反应活性。HOO⁻(H₂O)与甲酸甲酯仅通过B(AC)2通道反应。虽然微溶剂化降低了整体反应效率,但与未溶剂化类似物相比增强了所有阴离子的B(AC)2反应效率。这可以通过溶剂水分子以在整个反应过程中持续稳定负电荷 的方式参与B(AC)2反应来解释。