生物制造
合成生物学
生化工程
纳米技术
稀土
工业生物技术
生物浸出
生物分子
转化式学习
化学生物学
生物工程
环境友好型
生物材料
湿法冶金
商品化学品
化学
工程类
生物相容性材料
计算机科学
作者
Yangyi Liu,Juanjuan Su,Fan Wang,Huijing Cui,Kai Liu,Hongjie Zhang
出处
期刊:Nano Research
[Springer Science+Business Media]
日期:2026-01-21
卷期号:19 (4): 94908450-94908450
标识
DOI:10.26599/nr.2026.94908450
摘要
Rare-earth elements (REEs) are critical components of low-carbon technologies and advanced defense systems. However, their conventional extraction and separation processes, which rely on energy-intensive hydrometallurgy with harsh chemical reagents, pose significant environmental challenges. Synthetic biology offers a transformative alternative by enabling the programmable dissolution, precise molecular recognition, and selective capture of REEs under mild conditions. Specifically, engineered microbes can be designed to secrete tailored organic acids, siderophores, and redox-active metabolites for bioleaching REEs from ores, tailings, and industrial wastes. Concurrently, high-affinity biological binders—such as lanmodulin, lanthanide-binding peptides, and de novo–designed proteins—provide picomolar-level affinity and tunable selectivity ideal for biosorption. The integration of these functional motifs into advanced platforms, including immobilized sorbents, magnetic composites, and elastin-like polypeptides, enables continuous and regenerable REE recovery with minimal chemical input. Collectively, these biological strategies support an environmentally considerable approach to REE extraction and separation from diverse sources. Future efforts should focus on machine-learning-guided protein design, enhancing biomolecule stability, developing integrated leaching–adsorption bioreactors, improving tolerance to complex leachates, and incorporating biological modules into industrial flowsheets. These advances collectively establish synthetic biology as the foundation for a new paradigm in sustainable rare-earth production.
科研通智能强力驱动
Strongly Powered by AbleSci AI