NCFET to Rescue Technology Scaling: Opportunities and Challenges
Hussam Amrouch, Victor M. van Santen, Girish Pahwa, Yogesh Singh Chauhan, Jörg Henkel
Abstract
Negative Capacitance Field Effect Transistor (NCFET) is one of the promising emerging technologies that may overcome the fundamental limits of conventional CMOS technology. NCFET features a ferroelectric (FE) layer within the transistor's gate, which internally amplifies the voltage, allowing NCFET to operate at a lower voltage while sustaining performance at considerable energy savings. In this work, we raise awareness that n- and p-NCFET transistors are asymmetrically affected by the FE layer and show, for the first time, how this asymmetry results in unbalanced circuit performance (e.g., longer fall than rise propagation delay, reduced noise margins). As NCFET are meant to maintain performance while reducing power, we present a solution by scaling the number of fins in n-NCFET to regain symmetry. We optimize iteratively in conjunction with supply voltage scaling to find the minimal energy consumption while maintaining performance. In our first case study, we achieve at least 34% lower power consumption and thus 34% higher energy efficiency as the circuit exhibits identical propagation delay. However, our second case study reveals that NCFETs can consume 3× more power and energy than the FinFET design. In summary, not considering the asymmetry and replacing FinFET with current-matched NCFET results in unreliable circuits (timing violations). This work exemplifies how the power and energy consumption of a NCFET circuit might surpass that of a FinFET, if circuits are designed considering asymmetry and circuit metric matching.