Maximizing the Catalytic Function of Hydrogen Spillover in Platinum-encapsulated Aluminosilicates with Controlled Nanostructures

Overview

Journal Nat Commun

Specialty Biology

Date 2014 Feb 26

PMID 24566616

Citations 23

Authors

Juhwan Im

Hyeyoung Shin

Haeyoun Jang

Hyungjun Kim

Minkee Choi

Affiliations

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Abstract

Hydrogen spillover has been studied for several decades, but its nature, catalytic functions and even its existence remain topics of vigorous debate. This is a consequence of the lack of model catalysts that can provide direct evidences of the existence of hydrogen spillover and simplify the catalytic interpretation. Here we use platinum encapsulated in a dense aluminosilicate matrix with controlled diffusional properties and surface hydroxyl concentrations to elucidate the catalytic functions of hydrogen spillover. The catalytic investigation and theoretical modelling show that surface hydroxyls, presumably Brønsted acids, are crucial for utilizing the catalytic functions of hydrogen spillover on the aluminosilicate surface. The catalysts with optimized nanostructure show remarkable activities in hydro-/dehydrogenation, but virtually no activity for hydrogenolysis. This distinct chemoselectivity may be beneficial in industrially important hydroconversions such as propane dehydrogenation to propylene because the undesired hydrogenolysis pathway producing light hydrocarbons of low value (methane and ethane) is greatly suppressed.

Citing Articles

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