多孔负泊松比结构具有着优异的力学性能与独特的物理性能，本项目提出通过形状记忆智能材料与负泊松比多孔结构相结合，利用该智能材料的形状记忆特性记忆多孔结构的结构参数，通过主动调节其结构参数，进而实现多孔结构的力学与物理性能在一个极大的范围内变化可控，拓展了多孔结构在工程领域中的应用。主要研究内容包括：建立颗粒增强的形状记忆复合材料的本构模型，分析其在不同温度载荷下的应力-应变关系；根据复合材料结构设计与细观力学理论，开展形状记忆的多孔负泊松比结构的结构设计与多目标优化，提出兼顾结构刚度（初始结构）与实现结构主动控制和力学性能大范围可调的协同设计方案；研究负泊松比多孔结构的变形机理，及在变温与载荷条件下的微观基本胞元几何参数的变化规律，给出结构的等效力学性能的理论预测并加以验证。通过本项目的研究可为形状记忆的多孔负泊松比结构的未来工程应用，提供必要的理论依据和技术储备。

In this project, the novel porous auxetic structure with shape memory effect has been proposed, according to negative Poisson's ratio porous structure having excellent mechanical and unique physical properties. This novel intelligent structure combined the auxetic feature and shape memory characteristics to control its mechanical and physical properties to vary in a great range by adjusting its structural parameters. Such features could expand their potential application in the field of engineering. The main research contents include: the constitutive model of nano-particles reinforced shape memory composite will be established to analyze the stress-strain relationship under different temperature loads. Multi-objective optimization design of shape memory auxetic porous structure will be derived based on the design of composite materials and the theory of micromechanics. The collaborative design scheme is going to be proposed for considering the structural stiffness, active control structure and a wide range of adjustable mechanical properties. Through studying on the negative Poisson's ratio of deformation mechanism of porous structure and the variation law of microscopic basic cell geometry parameters under different temperature and load condition, the equivalent mechanical properties of porous structures will be presented and verified the theoretical predictions. This project may provide some necessary theoretical supports and technical reserves for the application of shape memory auxetic porous structure in the field of engineering.