College of Chemistry, Beijing Normal University, People's Republic of China.
J Biol Inorg Chem. 2011 Jun;16(5):745-52. doi: 10.1007/s00775-011-0775-x. Epub 2011 Apr 8.
The reaction mechanism of the hydration of acetylene to acetaldehyde catalyzed by W(IV)O(mnt)(2) (where mnt(2-) is 1,2-dicyanoethylenedithiolate) is studied using density functional theory. Both the uncatalyzed and the catalyzed reaction are considered to find out the origin of the catalysis. Three different models are investigated, in which an aquo, a hydroxo, or an oxo coordinates to the tungsten center. A first-shell mechanism is suggested, similarly to recent calculations on tungsten-dependent acetylene hydratase. The acetylene substrate first coordinates to the tungsten center in an η(2) fashion. Then, the tungsten-bound hydroxide activates a water molecule to perform a nucleophilic attack on the acetylene, resulting in the formation of a vinyl anion and a tungsten-bound water molecule. This is followed by proton transfer from the tungsten-bound water molecule to the newly formed vinyl anion intermediate. Tungsten is directly involved in the reaction by binding and activating acetylene and providing electrostatic stabilization to the transition states and intermediates. Three other mechanisms are also considered, but the associated energetic barriers were found to be very high, ruling out those possibilities.
[W(IV)O(mnt)(2)]-(2-)(mnt(2-)为 1,2-二氰基乙二硫醇根)催化乙炔水合生成乙醛的反应机理采用密度泛函理论进行了研究。考虑了未催化和催化反应,以找出催化的起源。研究了三种不同的模型,其中一个水合、一个羟基金属或一个氧基金属与钨中心配位。与最近关于钨依赖性乙炔水合酶的计算类似,提出了一种一壳层反应机理。乙炔底物首先以η(2)方式与钨中心配位。然后,钨配位的氢氧根离子激活一个水分子,对乙炔进行亲核攻击,形成乙烯阴离子和一个钨配位的水分子。接着,质子从钨配位的水分子转移到新形成的乙烯阴离子中间体。钨通过结合和激活乙炔以及为过渡态和中间体提供静电稳定作用直接参与反应。还考虑了另外三种机制,但发现相关的能垒非常高,排除了这些可能性。
