Pengcheng Huang, Yu Yan, Ricardo P. Martinho, Leon Lefferts, Bin Wang, Jimmy Faria Albanese
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引用次数: 0
摘要
酶可以通过局部改变溶剂与反应物之间的相互作用来精确控制化学反应的速度和选择性。为了将这些特性推广到异相催化剂中,我们采用了热膨胀性聚正异丙基丙烯酰胺(p-NIPAM)刷,将其粘合到含钯的二氧化硅球上。这些聚合物可在低温(32 °C)下与水分子形成氢键,从而使聚合物保持膨胀。亚硝酸盐氢化的详细反应动力学显示,p-NIPAM 在低温下可将表观活化障碍降低 3 倍。扩散有序光谱核磁共振和 ab initio 分子动力学模拟显示,当 p-NIPAM 存在时,表面附近的水分子流动性降低。这种限制扰乱了水与金属的相互作用,降低了亚硝酸盐的质子-电子转移还原障碍。值得注意的是,这种增强作用在高温下会消失,因为聚合物会自行塌缩,使钯暴露在未封闭的水中。这一过程的完全可逆性为创造具有可控水封闭性的同态催化剂打开了大门。
Water Confinement on Polymer Coatings Dictates Proton–Electron Transfer on Metal-Catalyzed Hydrogenation of Nitrite
Enzymes can precisely control the speed and selectivity of chemical reactions by modifying locally the solvent–reactant interactions. To extrapolate these attributes to heterogeneous catalysts, we have employed thermoresponsive poly n-isopropylacrylamide (p-NIPAM) brushes bonded to silica spheres containing palladium. These polymers can form hydrogen bonds with water molecules at low temperatures (<32 °C) allowing the polymer to stay swollen. Detailed reaction kinetics of nitrite hydrogenation showed that p-NIPAM decreases the apparent activation barrier by a factor of 3 at low temperatures. Diffusion-ordered spectroscopy nuclear magnetic resonance and ab initio molecular dynamics simulations showed that when p-NIPAM is present, water molecules near the surface are less mobile. This confinement perturbs the water interaction with the metal, reducing the barrier for the proton–electron transfer reduction of nitrite. Notably, this enhancement vanishes at high temperature as the polymer collapses on itself exposing the Pd to unconfined water. The fully reversible nature of this process opens the door for creating homeostatic catalysts with controlled water-confinement.
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