Insights Into the Impact of Pocket and Source Elevation in Vertical Gate Elevated Source Tunnel FET Structures.

In this paper, we investigate a vertical gate-based elevated tunnel source (TS) FET structure with and without a vertical n+ pocket and compare its performance with a lateral p-n-i-n TS (LTS) FET. The lined arrangement of gate not only provides a performance boosting as expected but it further allows the flexibility to minimize the degradations at higher pocket doping using source elevation. The vertical gate and pocket alignment overcome the full-depletion constraint of the LTS FET and maintain a better subthreshold swing (SS) over a higher range of pocket doping and width. An optimized average SS as low as ~26 mV/dec is achieved over five decades of current which is improved by 58% and 67%, respectively, as compared to the LTS and p-i-n tunnel field-effect transistors (TFETs) with an on-current enhancement of one order and $\sim 17\times $ , respectively. Furthermore, the gate-to-drain capacitance (${C} _{\textsf {GD}}$) in elevated source structures is a highly sensitive function of the pocket doping and can be significantly reduced by tuning the source elevation length ${L} _{\textsf {CV}}$ at higher pocket doping. At the same pocket conditions, a one order reduction in ${C} _{\textsf {GD}}$ is achieved with respect to the lateral configuration without compromising the intrinsic delay (${C} _{\textsf {GD}}\times {V} _{\textsf {DD}}/{I} _{\textsf {ON}})$. The circuit-level investigations show that due to the, otherwise, higher ${C} _{\textsf {GD}}$ in the LTS FET, the switching delay remains unaffected by the on-current boosting caused by higher pocket doping. However, it is drastically improved by ~23% in elevated source structures at a change from $4\times 10^{\textsf {19}}$ to $5\times 10^{\textsf {19}}$ /cm3. A faster switching delay ($\tau _{\textsf {p}}$) of ~116 ps is achieved at a ~33% reduced device base area. [ABSTRACT FROM AUTHOR]