In this thesis, we fabricate nMOSFET with recess source/drain and CESL(contact etch stop layer) on (110) substrate for channel strain and carrier mobility enhancement. Dopant activation is executed by the microwave anneal. Besides, from the result of material analysis, SiN film annealed by microwave shows with a tensile stress shift. This technique is used in device fabrication for tensile strain and mobility enhancement. From the result, CESL with microwave anneal for tensile enhancement technique improves driving current obviously. As gate length scales down to 0.2μm, recess source/drain structure with CESL with microwave anneal for tensile enhancement technique significantly enhances driving current. During SiN deposition, hydrogen diffuses to the interface of silicon and oxide to passivate dangling bonds. From charge pumping measurement, interface state density of SiN split is smaller than that of control split. From hot carrier stress analyses, the recess source/drain device shows a serious degradation after the hot carrier stress. In the process, channel hot electron would be trapped in the spacer. When the electrons flow through the spacer, Coulomb scattering would become serious in current-voltage measurement. As a result, current-voltage curves show a serious degradation. This phenomenon is confirmed from the result of shift of threshold voltage versus time under stress.