纳米机器人学
纳米技术
半导体
材料科学
化学
纳米颗粒
聚合物
纳米医学
抗菌活性
癌症治疗
纳米生物技术
半导体器件制造
生物相容性
量子点
纳米材料
作者
Qingdong Chai,Ziyi Zhou,Ziqi Zheng,Jie Zeng,Huannuo Tao,Guoxing Zhang,Zhenning Sun,Qirui Liang,Yanjun He,Kang Liang,DQ Zhu,Yang Lü,J. B. Liu,Tianyi Liu,Biao Kong
出处
期刊:ACS Nano
[American Chemical Society]
日期:2026-04-10
卷期号:20 (16): 12673-12690
标识
DOI:10.1021/acsnano.6c02416
摘要
Light-driven micro/nanorobots require semiconductor materials with efficient light harvesting and well-defined structural asymmetry to achieve high-performance propulsion. However, most reported systems rely on inorganic semiconductors with rigid band structures and limited stability, while polymeric semiconductors have been restricted by the lack of controllable asymmetric architectures. Here, we report a kinetically programmed one-pot strategy for constructing asymmetric polymeric semiconductor nanorobots with tunable island architectures. By regulating interfacial free energy and competitive nucleation kinetics, mesoporous aminophenol-formaldehyde resin/silica Janus nanoparticles with single-, dual-, and multi-island configurations are precisely synthesized. The resulting asymmetric nanostructures support synergistic light- and fuel-driven self-diffusiophoretic propulsion, allowing programmable motion behaviors. Benefiting from the autonomous motion and photocatalytic activity, the polymeric semiconductor nanorobots exhibit enhanced interaction with bacteria, deep biofilm penetration, and efficient diffusion of reactive oxygen species. This work establishes a general strategy for asymmetric polymeric semiconductor construction and highlights its potential in active antimicrobial and wound-healing nanomedicine.
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