Sustainable depolymerization of lignin into aromatic compounds using amphiphilic Anderson-type polyoxometalate catalysts
Ningxin Wei, Wenbiao Xu, Shujun Li, Junyou Shi
Abstract
Lignin serves as a primary abundant source of renewable aromatic compounds . Achieving efficient breakdown of lignin and retaining its aromatic properties is highly desirable but remains a challenging task. To address this challenge, we synthesized Anderson-type polyoxometalate (POM) catalysts, particularly [CTAC] 2 [CoMo 6 ]. We then investigated the effectiveness of the POM catalysts in the oxidative depolymerization of larch lignin. Under conditions of 160 °C, 1.0 MPa oxygen atmosphere, and a catalyst-to-substrate ratio of 1:5, we achieved a monomer yield of phenolic compounds at 12.43 wt%. The unsaturated coordination sites of Mo 5+ within the catalysts were identified as active sites, facilitating enhanced O 2 adsorption and activation. The enhanced O 2 adsorption significantly influenced the production of aromatic monomers from lignin. We observed that the catalysts effectively cleaved C C bonds in β -O-4 dimer compounds using lignin dimer model compounds. Notably, the [CTAC] 2 [CoMo 6 ] catalyst exhibited excellent stability across five cycles, maintaining its high efficiency in lignin depolymerization. This indicates that Anderson-type POM-based catalysts exhibit potential for sustainable conversion of biomass into valuable compounds and for enhancing lignin valorization processes.