中文摘要：

双轴应变技术被证实是一种能同时提高电子和空穴迁移率的颇有前景的方法;〈100〉沟道方向能有效地提升空穴迁移率.研究了在双轴应变和〈100〉沟道方向的共同作用下的空穴迁移率.双轴应变通过外延生长弛豫SiGe缓冲层来引入,其中,弛豫SiGe缓冲层作为外延底板,对淀积在其上的硅帽层形成拉伸应力.沟道方向的改变通过在版图上45°旋转器件来实现,这种旋转使得沟道方向在（001）表面硅片上从〈110〉晶向变成了〈100〉晶向.对比同是〈110〉沟道的应变硅pMOS和体硅pMOS,迁移率增益达到了130%;此外,在相同的应变硅pMOS中,沟道方向从〈110〉到〈100〉的改变使空穴迁移率最大值提升了30%.讨论和分析了

英文摘要：

Biaxial strain technology is a promising way to improve the mobility of both electrons and holes, while （100） channel direction appears as to be an effective booster of hole mobility in particular. In this work, the impact of biaxial strain together with （100） channel orientation on hole mobility is explored. The biaxial strain was incorporated by the growth of a relaxed SiGe buffer layer,serving as the template for depositing a Si layer in a state of biaxial tensile strain. The channel orientation was implemented with a 45^o rotated design in the device layout,which changed the channel direction from （110） to （100） on Si （001） surface. The maximum hole mobility is enhanced by 30% due to the change of channel direction from （110） to （100） on the same strained Si （s-Si） p-MOSFETs,in addition to the mobility enhancement of 130% when comparing s-Si pMOS to bulk Si pMOS both along （110） channels. Discussion and analysis are presented about the origin of the mobility enhancement by channel orientation along with biaxial strain in this work.