Title :
Single nanoparticle semiconductor devices
Author :
Ding, Yongping ; Dong, Ying ; Bapat, Ameya ; Nowak, Julia D. ; Carter, C.B. ; Kortshagen, R. ; Campbell, Stephen A.
Author_Institution :
Dept. of Electr. & Comput. Eng., Minnesota Univ.
Abstract :
Using a new technique in forming the cubic single-crystal silicon nanoparticles that are about 40 nm on a side, the authors have demonstrated a vertical-flow surround-gate Schottky-barrier transistor. This approach allows the use of well-known approaches to surface passivation and contact formation within the context of deposited single-crystal materials for device applications. It opens the door to the novel three-dimensional integrated circuits and new approaches to hyper integration. The fabrication process involves successive deposition and planarization and does not require nonoptical lithography. Device characteristics show reasonable turn-off characteristics and on-current densities of more than 107 A/cm2
Keywords :
Schottky gate field effect transistors; elemental semiconductors; nanoparticles; passivation; planarisation; silicon; 3D integrated circuits; contact formation; cubic single-crystal silicon nanoparticles; deposited single-crystal materials; nanoparticle semiconductor devices; planarization; surface passivation; surround-gate Schottky-barrier transistor; vertical-flow Schottky-barrier transistor; Fabrication; Lithography; Nanoparticles; Nanoscale devices; Passivation; Planarization; Semiconductor devices; Semiconductor materials; Silicon; Three-dimensional integrated circuits; FET; Schottky-barrier transistor; nanoparticle; silicon;
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2006.882047
