Two salicylic acid derivatives welded Zr-based hybrids relay catalysis: One-pot conversion of bio-based furfural to additive γ-valerolactone
Wang Jian-hua, Shuaihao Wang, Haoyu Peng, Zisheng Xiao, Qiong Xu, Xianxiang Liu, Dulin Yin, Wenzhou Zhong
Abstract
The development of multifunctional catalysts with multiple active sites is critical for upgrading bio-derived furfural into high-value γ -valerolactone. In this study, two Zr-based hybrid catalysts, Zr-SSA and Zr-3NSA, were synthesized via a straightforward hydrothermal method using 5-sulfosalicylic acid (SSA) and 3-nitrosalicylic acid (3NSA) as ligands coordinated with Zr 4+ , respectively. The sulfonic acid groups in Zr-SSA introduce significant Brønsted acidity, enabling efficient catalytic ring-opening of furfuryl alcohol to levulinate esters in alcoholic media. Besides, the nitro groups in Zr-3NSA enhance its Lewis acidity, improving its catalytic performance in transfer hydrogenation reactions. By adjusting the relative proportions of Zr-SSA and Zr-3NSA, the Brønsted-to-Lewis acidity ratio can be flexibly tuned, facilitating the cascade conversion of furfural to γ -valerolactone. Furthermore, a kinetic model was developed for this dual-catalyst relay system, enabling quantitative analysis of reaction pathways and providing mechanistic insights. This study demonstrates a novel strategy for the design of environmentally friendly and efficient Zr-based hybrid catalysts, highlighting their potential in the versatile conversion of lignocellulose-derived platform chemicals. • Zirconium-based hybrid catalysts were prepared via a simple solvothermal method. • 82.3 % yield of γ -valerolactone was achieved from furfural over dual-catalyst Zr-3NSA and Zr-SSA. • Influence of electron-withdrawing and coordination capacities of functional groups on the physical and chemical properties of hybrids. • Kinetic model and a plausible mechanism for dual-catalyst relay catalytic system were investigated.