Hydrophobic species-enabled acid-base multi-catalysis for stereoselective access to renewable trans -anethole.

trans -Anethole ( trans -AN) is widely applied in food, daily necessities, and pharmaceuticals and is typically available from inefficient natural oil extraction or complex organic transformations over mineral acid or noble metals. Here, a green and sustainable route was developed to stereoselectively produce trans -AN ( ca. 90% selectivity) over an organic polymeric phosphonate-hafnium catalyst (PAS-Hf) through the cascade transfer hydrogenation and dehydration of biomass-based 4'-methoxypropiophenone (4-MOPP), with an environmental impact factor ( E -factor) of 47.73. The porous structure and the enhanced hydrophobicity of the spherical catalyst PAS-Hf ensured the formation of more accessible and stable Lewis (Hf 4+ ) and Brønsted (SO 3 H) acid active sites, which could be used for rapid conversion of biomass-based 4-MOPP to AN (100% conversion, 97.2% yield) in 0.5-2 h (TOF: 9.3 h -1 ). Density functional theory (DFT) calculations elucidated that the addition of PAS-Hf could remarkably facilitate the overall conversion process by decreasing the reaction energy barrier (151.33 to 48.27 kJ mol -1 ) of the rate-determining step. The good thermal stability and heterogeneity of the bifunctional catalyst were responsible for its constant activity during at least five consecutive cycles. The synergistic/relay catalysis of Lewis acid-base and Brønsted acid species could be extended to more than ten kinds of aldehydes and ketones. This acid-base multi-catalytic protocol has considerable potential in cascade biomass conversion via heterogeneous catalysis without any base additive.