Device- and circuit-level variability due to random discrete dopant in resist- and spacer-defined nanoscale FinFETs

Abstract

In current CMOS technology, parameter variations are playing a vital role in limiting the benefits of downscaling, especially in the nanodomain. This work presents the investigation of random dopant fluctuation (RDF) in several possible line-edge roughness (LER)-induced fin shapes of spacer- (i.e., correlated LER) and resist- (i.e., uncorrelated LER) defined patterning techniques for a 14-nm FinFET structure. The three-dimensional (3-D) technology computer-aided design simulation on a large statistical ensemble has been carried out to analyze the impact of the RDF on various device parameters such as threshold voltage, drive current, off current, and drain-induced barrier lowering. It is observed that the impact of RDF on electrical parameters mainly depends on the fin shape and is dominant in all resist-defined FinFET structures. It is also found that the impact of RDF can diminish significantly using the spacer-defined patterning technique. Further, the impact of RDF in spacer- and resist-defined FinFET structures has been investigated for noise margins of 6-T static random access memories (SRAM). It is concluded that random dopant variations in SRAM performance offer better immunity in the case of spacer-defined FinFETs compared with resist-defined FinFETs.