Toward long-term retention-time single-electron-memory devices based on nitrided nanocrystalline silicon dots

Author

Huang, Shaoyun ; Arai, Kenta ; Usami, Kouichi ; Oda, Shunri

Author_Institution

Res. Center for Quantum Effect Electron., Tokyo Inst. of Technol., Japan

Volume

3

Issue

1

fYear

2004

fDate

3/1/2004 12:00:00 AM

Firstpage

210

Lastpage

214

Abstract

A memory capacitor with a structure of Si-SiO₂/nc-Si dots/silicon nitride films/SiO₂ was prepared by means of nc-Si dot deposition followed by N₂ plasma nitridation processes. The memory device offers dual memory nodes: nc-Si dots and traps in silicon-nitride films. An enlarged memory window in CV characteristics was observed in memory operations, due to the extra traps in silicon-nitrides. The charge-loss rate was found to be much smaller than that of single memory nodes using nc-Si dots only. The provided larger memory window (about twice the width) and longer retention time in the memory operations (three orders of magnitude) are discussed in terms of trap-assisted charging/discharging mechanisms.

Keywords

MOS capacitors; MOS memory circuits; electron traps; elemental semiconductors; nanostructured materials; nanotechnology; nitridation; plasma CVD; semiconductor quantum dots; semiconductor thin films; silicon; silicon compounds; single electron devices; CV characteristics; N₂ plasma nitridation; Si dot deposition; Si-SiO₂-SiN₂; charge-loss rate; dual memory nodes; enlarged memory window; long-term retention-time; memory capacitor; nitrided nanocrystalline silicon dots; silicon-nitride films traps; single-electron-memory devices; trap-assisted charging; trap-assisted discharging; Electron traps; Nanoscale devices; Nanotechnology; Nonvolatile memory; Plasma devices; Plasma properties; Semiconductor films; Silicon; Threshold voltage; US Department of Transportation;

fLanguage

English

Journal_Title

Nanotechnology, IEEE Transactions on

Publisher

ieee

ISSN

1536-125X

Type

jour

DOI

10.1109/TNANO.2004.824037

Filename

1278291