提高钛铝碳三元层状可加工陶瓷材料的硬度、强度及抗热腐蚀性能，开发简便易行的低成本制备工艺是其得以广泛应用的前提。本项目拟采用Ti、Al、TiC及金属氧化物MxOy（V2O5、Cr2O3、MoO3、Nb2O5等）为主要原料，以原位反应合成与高能球磨预合成工艺系统研究 (Ti,M)2AlC/Al2O3和(Ti,M)3AlC2/Al2O3系列材料粉体及块体的合成、结构及性能。通过DSC-TG、XRD、SEM、TEM、EDS等手段结合热力学与动力学计算研究不同体系的反应合成过程。探讨自生增强相及多元素固溶对该类材料基体相、增强相及晶界状态的影响，并分析其对材料力学性能及高温氧化和热液腐蚀性能影响的规律及其协同作用机理。通过优化组成、工艺并引入活性添加剂获得兼具力学、导电、导热及可加工性能于一身的多功能复合材料。为进一步认识该类材料的设计、制备、测试和机理，并促进其实用化奠定坚实的理论和实验基础。

To offer a novel simple and practical fabrication technology for modifying the hardness, strength and corrosion resistance is the prerequisite condition for further applications of the ternary laminated TiAlC machinable materials. In this work, series of powders and mass products of the (Ti,M)2AlC/Al2O3 and (Ti,M)3AlC2/Al2O3 composites will be synthesized by in situ reactions and/or high energy milling technology using the raw materials of Ti, Al, TiC and MxOy (V2O5, Cr2O3, MoO3, Nb2O5). The relation among the composition, processing, microstructure and properties will be investigated in detail. The reaction process in each system will be discussed and modified by DSC-TG, XRD, SEM, TEM, EDS, thermodynamic and kinetics calculations. Effects of the contents of the in situ formed Al2O3 and the third elements on the matrix phase, reinforcement, state of grain boundary and the mechanical properties, oxidation resistance, corrosion resistance will also be investigated. Moreover, the multiple functional nano laminated TiAlC based composites with excellent mechanical properties, thermal and electrical conduction, and machinability, will be successfully obtained through modifying the processing parameters and inial composition. These investigations will provide scientific and experimental references for further understand the design, fabrication, test and mechanisms, as well as practical applications of these materials.