电润湿作为先进高效的微流体操控技术，有效解决了电子器件微型化发展过程中由于机械摩擦造成器件寿命严重受损的问题。本项目针对微纳电子器件中复杂工况下的电润湿现象，采用理论分析、分子动力学模拟及实验验证等方法，从微观角度研究交变电场对液滴动态润湿特性的影响规律、液滴微观结构与固液界面的耦合动力学行为、壁面润湿梯度与外电场对液滴的协同驱动机制等科学问题。本项目一方面重点探索电场作用下壁面极性、润湿梯度、微观形貌等对微纳液滴润湿过程及平衡状态的调控机制，为解释电润湿接触角饱和现象提供理论支撑；另一方面深入研究直流电场方向与极性、交流电场波形与频率以及非周期交变电场等电场特性对液滴内部微观结构、固液气界面动力学行为的影响规律，进而明确交变电场减小接触角滞后的微观机理。本项目体现了多学科的交叉融合，其成果将丰富电润湿基础理论体系，推动我国微纳米电子器件微型化发展。

As an advanced micro-droplet control technology with highly efficient, electrowetting is the key method to solve the problem that device life is seriously damaged due to mechanical friction with the miniaturization development of electronic device. According to the complex electrowetting phenomenon in the micro-nano electronic devices, theoretical analysis, molecular dynamics simulation and experimental verification method are applied to study collaborative scientific problems from the microscopic angle. There are the effect of alternating electric field on the droplet dynamic wetting characteristic, droplet microstructure and coupling dynamics behavior of the solid-liquid interface and driving mechanism of surface wetting gradient and electric field on the droplet. This project focuses on exploring the regulatory mechanism of surface polarity, wetting the gradient, and the microstructure on the wetting process and equilibrium of droplet in the present of electric field. It will provide theoretical support to explain the contact angle saturation in electroertting. On the other hand, further research will be carried out on the effect of electric field characteristics, such as the direction and polarity of direct electric field and the waveform and frequency of alternating electric field on droplet internal microscopic structure, the influence law of gas solid liquid interface dynamics behavior. And then the micro mechanism of the alternating electric field decrease the contact Angle hysteresis will be cleared. The project shows the intercross and coalescence among the multi-subjects. The achievements of this project will promote the basic theory system of the electrowetting and the miniaturization development of China micro/nano electronic device.