压电式压力传感器由于响应速度快、灵敏度高、线性度好等优点，在电子皮肤触觉传感领域表现出良好的应用前景。本项目针对压电式触觉传感器电学性能与力学柔韧性相互矛盾的关键问题，立足于ZnO/P(VDF-TrFE)压电复合材料的层次化设计及柔性器件制备，综合利用ZnO纳米棒有序阵列的高电学性能和聚合物的强力学柔韧性，并结合微纳图案修饰技术，研制基于层次化ZnO/P(VDF-TrFE)压电复合材料的柔性触觉传感器阵列。项目将系统研究具有3D层次结构的微纳图案化ZnO/P(VDF-TrFE)柔性压电复合材料的可控构筑，深入分析ZnO纳米棒有序阵列与P(VDF-TrFE)的界面作用关系，揭示不同维度ZnO与聚合物间的力电耦合协同作用规律，阐明微纳图案化设计和层次化复合结构构建对提升ZnO/P(VDF-TrFE)复合材料压电性和力学柔韧性的调控机理，从而为柔性电子皮肤触觉传感器设计和制备提供一定的科学依据。

Due to the advantages of fast response, high sensitivity and good linearity, the piezoelectric sensor has a good application prospect in the field of electronic skin tactile sensing. The complementary use of high electrical properties of piezoelectric ceramics and good mechanical flexibility of piezoelectric polymer combined with micro/nano pattern modification technology allows us to construct a tactile sensor based on hierarchical ZnO/P(VDF-TrFE) composites supported on the flexible substrate, and hence simultaneously reconcile the contradiction between electrical properties and mechanical flexibility of piezoelectric tactile sensor. The present research focuses on the hierarchical design of ZnO/P(VDF-TrFE) piezoelectric composite materials and the fabrication of flexible devices. We will study the effect of hierarchical structure design on the piezoelectric properties and mechanical properties of the composites, investigate the relationship between the parameters of micro/nano pattern and the electrical properties of the laminate, reveal the synergistic effect of piezoelectric properties between piezoelectric ceramics and polymers, and further clarify the mechanism of controling the electrical properties and mechanical properties of piezoelectric composite materials through micro/nano pattern modification, which will provide a guidance and reference for the design of new flexible electronic skin tactile.