生物炼制
生物净化
绿色化学
生命周期评估
生化工程
可持续发展
木质纤维素生物量
纤维素乙醇
化学
工业生态学
环境影响评价
深共晶溶剂
持续性
半纤维素
生物量(生态学)
乙二醇
过程(计算)
环境科学
工艺工程
石油化工
工程类
生物过程
环境经济学
清洁生产
化石燃料
原材料
炼油厂
三元运算
废物管理
生物燃料
作者
Han Gao,Yonglan Huang,Yun Wang,Jinliu Xiao,Yunkai Yu,Quancheng Liu,Jian Zhang,Zhiwei Wang,Qingshan Luo
标识
DOI:10.1021/acssuschemeng.5c05904
摘要
Advancing scalable and sustainable biorefinery technologies is vital for supporting the circular bioeconomy and reducing the reliance on fossil resources. In this study, we introduce a multiscale life cycle assessment (mLCA) framework to evaluate biomass valorization systems by integrating green solvent design, process efficiency, scale-up potential, environmental burdens, and techno-economic implications. Guided by this framework, we developed a ternary deep eutectic solvent (DES) composed of choline chloride, lactic acid, and ethylene glycol for the pretreatment of lignocellulosic biomass. Compared to conventional binary DES systems, the ternary DES demonstrated superior selectivity for lignin and hemicellulose removal, achieving a saccharification efficiency of 97.38% while maintaining high process efficiency and solvent recovery. The prospective life cycle assessment (pLCA) predicts that after scaling the processes from laboratory to industrial scale, most environmental impact indicators are significantly reduced (27.84–97.82%), although impacts in some categories, including marine eutrophication, stratospheric ozone depletion, and land use, increased─likely attributable in part to ethylene glycol. Monetized environmental assessment further confirmed that all environmental risk index (ERI) values remained below 1, suggesting overall environmental and regulatory feasibility. These findings underscore the value of coupling green chemistry with life cycle thinking to enable the sustainable industrial deployment of high-efficiency biorefining technologies.
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