Efficient Catalytic Production of Hydrogen Peroxide Using Tin‐containing Zeolite Fixed Palladium Nanoparticles with Oxidation Resistance.

Liu, Yifeng; Liu, Zhaoqing; Zhang, Jian; Xiao, Feng‐Shou; Cao, Xiaoming; Wang, Liang

The metal surfaces tend to be oxidized in air through dissociation of the O−O bond of oxygen to reduce the performances in various fields. Although several ligand modification routes have alleviated the oxidation of bulky metal surfaces, it is still a challenge for the oxidation resistance of small‐size metal nanoparticles. Herein, we fixed the small‐size Pd nanoparticles in tin‐contained MFI zeolite crystals, where the tin acts as an electron donor to efficiently hinder the oxidation of Pd by weakening the adsorption of molecular oxygen and suppressing the O−O cleavage. This oxidation‐resistant Pd catalyst exhibited superior performance in directly synthesizing hydrogen peroxide from hydrogen and oxygen, with the productivity of hydrogen peroxide at ≈10,170 mmol gPd−1 h−1, steadily outperforming the catalysts tested previously. This work leads to the hypothesis that tin is an electron donor to realize oxidation‐resistant Pd within zeolite crystals for efficient catalysis to overcome the limitation of generally supported Pd catalysts and further motivates the use of oxidation‐resistant metal nanoparticles in various fields.

HYDROGEN peroxide; PALLADIUM; METAL nanoparticles; HYDROGEN production; ZEOLITES; ELECTRON donors; TIN; OXYGEN

Angewandte Chemie, 2023, Vol 135, Issue 47, p1

0044-8249

Academic Journal

10.1002/ange.202312377