A simulation perspective: The potential and limitation of Ge GAA CMOS
The electrical characteristics of <110> n/p Ge nanowire transistors (NWTs) with the cross section of 6×6nm2 have been studied. The ION performance and the subthreshold swing are simulated by multi-subband Boltzmann transport equation and ballistic quantum transport solvers, respectively. The performance of <110> nGe NWTs is sensitive to the barrier height of interfacial layer due to highly-anisotropic Λ-valleys. The dimension-dependent k·p parameters based on tight-binding full band are used to address the strong confinement of pGe NWTs. Comparing to Si NWTs, the intrinsic ION is twice as high for both n/p Ge NWTs at 28nm channel length. As the channel length is scaled down, such ION benefit is maintained till the tunneling effect comes in and degrades the subthreshold swing. authors: Sheng-Kai Su, Edward Chen, and Jeff Wu
Logic
Transistor Structure
TSMC CMOS logic technology relied on planar transistor structures until 2014, when FinFETs were introduced into production with our 16nm technology. The FinFET structure resolved a fundamental limitation of planar device scaling, namely the poor electrostatic control of the channel at short gate lengths. FinFETs also enabled a partial decoupling of the transistor density scaling from device effective width scaling, which is an important feature for attaining increased transistor current per unit footprint of transistors. These FinFET characteristics enabled significant reduction of the power supply voltage as compared to planar transistors. FinFET also presents new degrees of freedom for power performance optimization, which contributed to significant enhancements in energy efficiency from 16nm to our most recently introduced 5nm technology node.
TSMC research and development continues to explore next-generation structures such as stacked nanowires or stacked nanosheets in our quest for new heights in computing performance and energy efficiency for future technology nodes.
