Scaling Theory of Electrically Doped 2D Transistors

Author

Ilatikhameneh, Hesameddin ; Klimeck, Gerhard ; Appenzeller, Joerg ; Rahman, Rajib

Author_Institution

Dept. of Electr. & Comput. Eng., Purdue Univ., West Lafayette, IN, USA

Volume

36

Issue

7

fYear

2015

fDate

Jul-15

Firstpage

726

Lastpage

728

Abstract

In this letter, it is shown that the existing scaling theories for chemically doped transistors cannot be applied to the novel class of electrically doped 2D transistors and the concept of equivalent oxide thickness (EOT) is not applicable anymore. Hence, a novel scaling theory is developed based on analytic solutions of the 2D Poisson equation. Full band atomistic quantum transport simulations verify the theory and show that the critical design parameters are the physical oxide thickness and distance between the gates. Accordingly, the most optimized electrically doped devices are those with the smallest spacing between the gates and the thinnest oxide, and not the smallest EOT.

Keywords

Poisson equation; field effect transistors; semiconductor device models; 2D Poisson equation; critical design parameters; electrically doped 2D transistors; equivalent oxide thickness; full band atomistic quantum transport simulations; scaling theory; Analytical models; Dielectric constant; Doping; Junctions; Logic gates; Semiconductor process modeling; Transistors; 2D FETs; electrical doping; scaling theory;

fLanguage

English

Journal_Title

Electron Device Letters, IEEE

Publisher

ieee

ISSN

0741-3106

Type

jour

DOI

10.1109/LED.2015.2436356

Filename

7111272