Effects of Sn_xPt_y Alloy Structures on the Performance of SnPt Catalysts for the Selective Hydrogenation of Unsaturated Aldehydes to Unsaturated Alcohols

Abstract

The development of next-generation heterogeneous catalysts for the chemoselective hydrogenation of unsaturated aldehydes to unsaturated alcohols requires extensive structural understanding of active catalyst sites. In the case of SnPt catalysts, the presence of metallic Sn and the formation of Sn–Pt alloys are believed to be key factors strongly affecting the selectivity of unsaturated alcohol formation. This review describes the relationship between the catalytic crotonaldehyde (CH₃–CH=CH–CHO) hydrogenation performance of supported and non-supported SnPt catalysts and the structure of the component Sn_xPt_y alloys, which reveal that at the same Sn/Pt atomic ratio, the composition of the produced Sn_xPt_y alloys depends on the preparation method. The Sn₁Pt₃, Sn₁Pt₁, and Sn₂Pt₁ phases identified in SnPt catalysts exhibited higher crotyl alcohol (CH₃–CH=CH–CH₂OH) formation selectivity than the monometallic Pt phase. Furthermore, the Sn₁Pt₁ and Sn₂Pt₁ phases showed lower crotonaldehyde conversion than the Pt phase. Formation of Sn oxides over the supported SnPt catalysts was confirmed with excess amount of Sn. The crotyl alcohol selectivity increased with the transition from Sn₁Pt₃ to Sn₁Pt₁, then decrease with the further transition to the more Sn-rich Sn₂Pt₁ phase. Thus, the Sn₁Pt₁ alloy phase was concluded to be the most effective bimetallic SnPt structure for the selective formation of crotyl alcohol.