Relevance of Device Cross Section to Overcome Boltzmann Switching Limit in 3-D Junctionless Transistor.

In this paper, the requirements of device cross section and aspect ratio (AR) are examined to facilitate steep switching in heavily doped 3-D multiple gate junctionless (JL) transistors. It is shown through well-calibrated simulations and physical insights that the sharp OFF-to- ON switching action is predominantly governed by the area of cross section (${A} _{\textsf {cross}}$) instead of the gate length. A 3-D JL architecture preferably oriented toward a planar topology, i.e., with wider fin and low AR, is conducive for steep switching as a greater bulk area is available for impact ionization. On the contrary, narrow vertical architectures with AR > 1 suppress ${A} _{\textsf {cross}}$ in the bulk and are less likely to support the steep current transition. Steep switching specific scaling methodology is showcased to attain a sharp increase in drain current with a sub-60 mV/decade swing in a tri-gate JL transistor along with an associated negative value of total gate capacitance. [ABSTRACT FROM AUTHOR]