Monolithically Cointegrated Tensile Strained Germanium and In_xGa_1-xAs FinFETs for Tunable CMOS Logic

In this article, we have evaluated the merits of monolithically cointegrated alternate channel complementary metal-oxide-semiconductor (CMOS) device architecture, utilizing tensile strained germanium ( $\boldsymbol {\varepsilon }$ -Ge) for the p-channel FinFET and variable indium (In) compositional In _x Ga _1-x As ( $0.10\le {x} \le0.53$ ) for the n- channel FinFET. The device simulation models were calibrated using the experimental results of Ge and InGaAs FinFETs and subsequently transferred to the cointegrated Ge and In _x Ga _1-x As structure while keeping the device simulation parameters fixed. The device parameters, such as ${V}_{\text {T}}$ , ${I}_{\text {on}}$ , ${I}_{\text {off}}$ , and subthreshold-swing (SS), were determined for identical fin dimensions for n- and p-channel FinFETs as a function of In composition that alters the tensile strain in Ge. These parameters are controllable during the heteroepitaxial growth by varying In composition in In _x Ga _1-x As. $\boldsymbol {\varepsilon }$ -Ge p-FinFET is shown to be superior in terms of SS and ${I}_{\text {on}}/{I}_{\text {off}}$ ratio compared with other competing architectures. The cointegrated architecture of CMOS inverter exhibited an optimum performance over a range of In compositions from 20% to 40% while driving fan-out fan-out 1 (FO-1) and FO-4 load configurations. In addition, the CMOS inverter with symmetric rise and fall times as well as noise-immune functionality demonstrated 150 GHz of operating frequency with 30-nW total power dissipation at 20% In composition, and hence a superior power-delay-product comparable with International Technology Roadmap for Semiconductors (ITRS) standards. Moreover, the three-stage CMOS ring oscillator performance was evaluated with various In compositions to be stable and power efficient. Thus, the cointegrated approach has a potential to: 1) simplify large-scale CMOS integration and 2) be compatible with optoelectronic materials.