Â鶹ÒùÔº

MAX phases boost electrocatalytic biomass upgrading

Biomass is among the most abundant renewable resources on Earth. Through catalytic conversion, biomass can upgrade into a series of fuels and chemicals which can substitute traditional fossil resources, thus playing a crucial role in achieving the "carbon peaking and carbon neutrality" target.

A group of Chinese scientists have developed a novel MAX phase with single-atom-thick cobalt layers, achieving high-efficiency electrocatalysis of 5-hydroxymethylfurfural (HMF) oxidation coupled with hydrogen evolution. The work is in the Chemical Engineering Journal.

MAX phases are a family of layered ternary metal carbides or nitrides that have attracted great attention as structural materials due to their outstanding structural diversities, mechanical properties, and application potential.

Prof. Zhang Jian's team at the Ningbo Institute of Materials Technology and Engineering (NIMTE) of the Chinese Academy of Sciences (CAS), in cooperation with Prof. Huang Qing's team at NIMTE and Prof. LI Youbing at Soochow University, introduce cobalt, a highly catalytic and cost-effective transition metal, into the A-site of MAX phases.

The obtained V₂(Sn_2/3Co_1/3)C MAX phase was applied as a high-efficiency electrocatalyst for the HMF oxidation along with hydrogen evolution in an alkaline electrolyte. This achieved complete biomass HMF conversion and a 94.4% 2,5-furandicarboxylic acid (FDCA) yield at 1.60 V throughout six hours in the two-electrode system.

Additionally, the FDCA production rate reached 8.02±0.64 mmol_FDCA⋅g_cat.^-1⋅h^-1 in the 100 mM HMF electrolyte, surpassing many traditional electrocatalysts and thermocatalysts.

Density functional theory (DFT) calculations indicated that the Co-Sn synergy in the A-site facilitated the adsorption and electrocatalytic conversion of HMF, therefore transforming MAX phases from structural materials into functional materials.

Moreover, HMF can significantly inhibit the surface reconstruction of MAX phases and competitive oxygen evolution reaction. Therefore, the structure of MAX phases remained intact even after the electrolysis in a harsh 1 M KOH alkaline electrolyte.

The excellent electrocatalytic performance and structural stability of biomass upgrading demonstrated the broad potential of MAX phases for applications in energy storage, green catalysis, and other challenging chemical environments.