Department of Chemistry and Chemical Biology Baker Laboratory, Cornell University Ithaca, New York 14853-1301, United States.
J Org Chem. 2010 Dec 17;75(24):8392-9. doi: 10.1021/jo101505x. Epub 2010 Nov 16.
A combination of NMR, kinetic, and computational methods are used to examine reactions of lithium diethylamide in tetrahydrofuran (THF) with n-dodecyl bromide and n-octyl benzenesulfonate. The alkyl bromide undergoes competitive S(N)2 substitution and E2 elimination in proportions independent of all concentrations except for a minor medium effect. Rate studies show that both reactions occur via trisolvated-monomer-based transition structures. The alkyl benzenesulfonate undergoes competitive S(N)2 substitution (minor) and N-sulfonation (major) with N-sulfonation promoted at low THF concentrations. The S(N)2 substitution is shown to proceed via a disolvated monomer suggested computationally to involve a cyclic transition structure. The dominant N-sulfonation follows a disolvated-dimer-based transition structure suggested computationally to be a bicyclo[3.1.1] form. The differing THF and lithium diethylamide orders for the two reactions explain the observed concentration-dependent chemoselectivities.
采用 NMR、动力学和计算方法研究了在四氢呋喃(THF)中,二乙胺锂与正十二烷基溴和正辛基苯磺酸酯的反应。该烷基溴经历 S(N)2 取代和 E2 消除的竞争反应,其比例与所有浓度无关,除了轻微的介质效应外。速率研究表明,两种反应都通过三溶剂化单体基过渡态发生。该烷基苯磺酸酯经历 S(N)2 取代(次要)和 N-磺化(主要)反应,在低 THF 浓度下促进 N-磺化。S(N)2 取代反应通过计算上表明涉及环状过渡态结构的可溶剂化单体进行。计算上表明,主要的 N-磺化反应遵循可溶剂化二聚体基过渡态,该过渡态为双环[3.1.1]形式。两种反应的 THF 和二乙胺锂的不同顺序解释了观察到的浓度依赖性化学选择性。