发展系统的自组装方法与理论,开发高光学活性多层次手性组装体,揭示手性产生及跨尺度传递、放大、调控规律,探索在光电显示、防伪加密等领域的多功能应用。
Developing systematic self-assembly methods and theories, creating multi-level chiral assemblies with high optical activity, revealing the laws of chirality generation and its cross-scale transfer, amplification, and regulation, and exploring multifunctional applications in the fields of optoelectronic displays, anti-counterfeiting encryption, etc.
发展纳米流体体系,建立膜尺度限域纳米孔中纳米流体输运的新机制,并指导分子或离子分离膜材料的发展;面向大宗有机化学品分离,发展分子分离膜材料,解决精细化工、石油、石化等领域在精细分离方面的需求。
Developing novel nanofluidic systems, establishing new mechanisms for nanofluidic transport in confined nanopores, and guiding the development of molecular or ionic separation materials. Addressing the fine separation needs in fields such as fine chemicals, petroleum, and petrochemicals through development of molecular separation membrane materials.
针对热催化小分子转化与精细化学品合成、光催化甲烷选择性氧化与偶联、电催化水解制绿氢与二氧化碳还原等重要反应体系,发展多级次自组装构建高性能纳米催化剂的可控构筑方法,结合先进原位表征手段揭示多组装基元间的协同作用本质和结构演变规律。
For essential reaction systems such as the conversion of small molecules and the synthesis of fine chemicals via thermos-catalysis, selective oxidation and coupling of CH4 via photo-catalysis, and the production of green H2 and reduction of CO2 via electro-catalysis, developing methodology for precisely constructing high-performance catalysts through hierarchical self-assembly. Employing advanced in-situ characterization techniques to reveal the nature of synergistic effects between multiple assembly units and the dynamic structural evolution.
