核壳钯纳米粒子@金属有机骨架作为级联反应的多功能催化剂。

Core-shell palladium nanoparticle@metal-organic frameworks as multifunctional catalysts for cascade reactions.

机构信息

Laboratory for Nanomaterials, National Center for Nanoscience and Technology , Beijing, 100190, P. R. China.

出版信息

J Am Chem Soc. 2014 Feb 5;136(5):1738-41. doi: 10.1021/ja411468e. Epub 2014 Jan 27.

Abstract

Uniform core-shell Pd@IRMOF-3 nanostructures, where single Pd nanoparticle core is surrounded by amino-functionalized IRMOF-3 shell, are prepared by a facile mixed solvothermal method. When used as multifunctional catalysts, the Pd@IRMOF-3 nanocomposites exhibit high activity, enhanced selectivity, and excellent stability in the cascade reaction. Both experimental evidence and theoretical calculations reveal that the high catalytic performance of Pd@IRMOF-3 nanocomposites originates from their unique core-shell structures.

摘要

均匀的核壳结构 Pd@IRMOF-3 纳米结构，其中单个 Pd 纳米颗粒核被氨基功能化的 IRMOF-3 壳所包围，是通过一种简便的混合溶剂热方法制备的。当用作多功能催化剂时，Pd@IRMOF-3 纳米复合材料在级联反应中表现出高活性、增强的选择性和优异的稳定性。实验证据和理论计算都表明，Pd@IRMOF-3 纳米复合材料的高催化性能源于其独特的核壳结构。

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核壳钯纳米粒子@金属有机骨架作为级联反应的多功能催化剂。

Core-shell palladium nanoparticle@metal-organic frameworks as multifunctional catalysts for cascade reactions.

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