Variable Length and Temperature-Dependent Analysis of MLGNR at Nano-Scale Regime

Abstract

In this paper, a thermally aware equivalent single conductor is proposed, along with analytical modeling to evaluate the parasitic parameters of multilayer graphene nanoribbon (MLGNR) as interconnect, and its performance is analyzed in terms of delay and power delay product (PDP) for 32[Formula: see text]nm, 22[Formula: see text]nm and 16[Formula: see text]nm technology nodes at variable global interconnect lengths (500–2000[Formula: see text]m). It was examined that with rising temperature, there is a strident decrease in the mean free path (MFP) of GNR interconnect, which further influences its own resistance at global length (2000[Formula: see text][Formula: see text]m) for all three technology nodes. The simulation tool Simulation Program with Integrated Circuit Emphasis (SPICE) is used to estimate and compare MLGNR performance in terms of signal delay and PDP for three different technology nodes. It is revealed from the outcomes that the propagation delay and PDP increase at long interconnects (500–2000[Formula: see text][Formula: see text]m) over a temperature range of 200–500[Formula: see text]K for deep submicron technology nodes (16[Formula: see text]nm, 22[Formula: see text]nm and 32[Formula: see text]nm). A similar investigation was performed on the copper interconnect, and it was discovered that the MLGNR performs better in terms of delay and PDP at global levels with a temperature range of 200–500[Formula: see text]K for nano-scaled technology nodes (32[Formula: see text]nm, 22[Formula: see text]nm and 16[Formula: see text]nm).