Negative Capacitance as Digital and Analog Performance Booster for Complementary MOS Transistors

Boltzmann tyranny poses a fundamental limit to lowering the energy dissipation of conventional MOS devices, a minimum increase of the gate voltage, i.e. 60 mV, is required for a 10-fold increase in drain-to-source current at 300 K. Negative Capacitance (NC) in ferroelectric materials is proposed in order to address this physical limitation of CMOS technology. A polarization destabilization in ferroelectrics causes an effective negative permittivity, resulting in a differential voltage amplification and a reduced subthreshold swing when integrated into the gate stack of a transistor. Recent demonstrations of negative capacitance concerned mainly n-type MOSFETs and their subthreshold slope. An effective technology booster should be capable of improving the performance of both n- and p-type transistors. In this work, we report a significant enhancement in both digital (subthreshold swing, on-current over off-current ratio, and overdrive) and analog (transconductance and current efficiency factor) FoM of commercial 28nm CMOS process by exploiting a PZT capacitor as the negative capacitance booster. Accordingly, a sub-thermal swing down to 10 mV/decade together with an enhanced current efficiency factor up to 10$^5$ V$^{-1}$ is obtained in both n- and p-type MOSFETs at room temperature. The overdrive voltage is enhanced up to 0.45 V, leading to a supply voltage reduction of 50\%.