TY - JOUR AU - Yuan, Qiang AU - Wang, Hao AU - Ding, Weiping AU - Zhu, Yan PY - 2026 TI - Bioethanol conversion to ethyl acetate via one-step catalysis JO - Green Chemical Engineering SN - 2096-9147 SP - 370 EP - 379 VL - 7 IS - 4 AB - As the sole renewable organic carbon source in nature, biomass holds irreplaceable strategic significance in sustainable energy systems. The catalytic conversion of biomass-derived ethanol into high-value multi-carbon chemicals not only provides a crucial alternative to fossil-based routes for producing bulk chemicals but also represents a key breakthrough toward achieving green chemistry and circular economies. In the realm of biomass-derived platform molecules, ethyl acetate (EA) occupies a pivotal role as an industrial solvent and a fundamental chemical compound. Its annual demand, estimated to be in the millions of tons, has garnered significant attention due to the pressing need for green synthesis technologies. Notably, the one-step catalytic synthesis of EA from bioethanol has emerged as a research hotspot in catalysis, owing to its unique advantages: renewable feedstock, clean production processes, exceptional atom economy, and the generation of high-purity hydrogen as a valuable byproduct. This review systematically introduces recent advancements in ethanol dehydrogenative coupling for EA production, with a focus on catalyst design strategies—including active site engineering and support engineering and their critical roles in regulating reaction pathways. By establishing comprehensive correlations among catalyst architecture, mechanistic pathways, and catalytic performance, we elucidate the merits and limitations of existing catalytic systems. Furthermore, the comprehensive analysis of structure-activity relationships in this work provides viable guidelines for the design of next-generation catalytic systems, which will ultimately advance the development of economically viable and sustainable ethanol valorization technologies. UR - https://doi.org/10.1016/j.gce.2025.07.005 DO - 10.1016/j.gce.2025.07.005