Title :
Effect of Oxidation-Induced Tensile Strain on Gate-All-Around Silicon-Nanowire-Based Single-Electron Transistor Fabricated Using Deep-UV Lithography
Author :
Sun, Yongshun ; Rusli ; Singh, Navab
Abstract :
We report on the electrical characteristics of gate-all-around silicon nanowires (SiNWs) based single-electron transistors (SETs) operating at room temperature. The SiNWs, fabricated using CMOS compatible conventional KrF lithography, have a diameter of around 3 nm and different lengths ranging from 200 to 500 nm. Coulomb blockade oscillations are found to be dependent on the length of the SiNWs, more prominent for longer than shorter SiNWs. For the shortest device of 200 nm, no oscillation is seen and the ID - VG curve reverts to that of a typical MOSFET. The results are interpreted in terms of the effect of SiNW length on the oxidation-induced tensile strain, and consequently, the tunneling barrier height developed in the wires. The study reveals that the SiNW length is a crucial parameter in the design of SiNW-based SETs.
Keywords :
Coulomb blockade; elemental semiconductors; internal stresses; nanofabrication; nanowires; oxidation; silicon; single electron transistors; tunnelling; ultraviolet lithography; CMOS compatible KrF lithography; Coulomb blockade oscillations; Si; deep-UV lithography; electrical characteristics; gate-all-around silicon-nanowire-based single-electron transistor; oxidation-induced tensile strain; silicon nanowire length; size 200 nm to 500 nm; temperature 293 K to 298 K; tunneling barrier height; Logic gates; Nanowires; Oscillators; Temperature measurement; Tensile strain; Tunneling; Coulomb oscillation; Deep-UV lithography; silicon nanowires (SiNWs); single-electron transistor (SET); tensile strain;
Journal_Title :
Nanotechnology, IEEE Transactions on
DOI :
10.1109/TNANO.2011.2132736
