Contents I. Introduction
Because of the advancement in technology and demands for high packing density, high speed and low power integrated chips (ICs), it is highly desirable to scale down transistor’s channel length. This task has proven to be quite challenging in planar CMOS structure owing to the problem of short channel effects (SCE). When a transistor is properly biased with the appropriate gate-source voltage (VGS), the electrons are able to summon the barrier and flow from the source terminal to the drain terminal. In short channel device, the application of high drain voltage tends to lower the potential barrier for electrons to flow from the source to the drain. The IOFF current is increased, which reduces the ION/IOFF ratio and causes shift in the threshold voltage (ΔVth). In addition, the subthreshold slope (SS) is degraded and becomes difficult to switch off the transistor. This phenomenon is known as drain induced barrier lowering (DIBL). The planar MOSFETs also suffer from mismatch in Vth as a result of random dopant fluctuations [1]. However, this atomistic effect is less significant in FinFET due to its lightly doped body [2]. Over the years, FinFET technology is replacing the conventional planar structure MOSFETs because it offers better electrostatic control of the channel and suppressed short channel effects, higher ION/IOFF ratio, relatively nadesi1@lsu.edu ideal subthreshold slope, low junction capacitances, lower static leakage current, high switching speed and lower switching voltage e.t.c. Double gate FinFET also has higher hole mobility than bulk FET. Nevertheless, it has higher parasitic capacitances, which causes more delay in FinFET-based circuits.
