Fermi-Level Pinning in Nanocrystal Memories

Author

Hou, Tuo-Hung ; Ganguly, Udayan ; Kan, Edwin C.

Author_Institution

Sch. of Electr. & Comput. Eng., Cornell Univ., Ithaca, NY

Volume

28

Issue

2

fYear

2007

Firstpage

103

Lastpage

106

Abstract

The nanocrystal (NC) work-function engineering, which plays an important role on the NC memory characteristics such as memory window and retention time, were long regarded as a matter of choice on NC materials. In this letter, we report opposite polarities of charge storage in Au NC memories with different control oxides. The effective NC work function is found to be not only a bulk property of the NC, but also governed by the interface with surrounding dielectric, as a result of the Fermi-level pinning. By replacing Au NCs with C₆₀ molecules, we also show the pinning effect generally exists at quantum-dot-based devices with high density of interface states. This fundamental interface property should be taken into account in the selection of NC and dielectric materials for the NC memory optimization

Keywords

Fermi level; carbon; dielectric materials; digital storage; gold; nanoelectronics; nanostructured materials; work function; Au; C₆₀; Fermi-level pinning; dielectric materials; memory optimization; nanocrystal memory; nanocrystal work-function engineering; nonvolatile memories; quantum-dot devices; Chemicals; Dielectric materials; Gold; Inorganic materials; Interface states; Nanocrystals; Nonvolatile memory; Potential well; Silicon; Tunneling; Fermi-level pinning; nanocrystal (NC); nonvolatile memories; work function;

fLanguage

English

Journal_Title

Electron Device Letters, IEEE

Publisher

ieee

ISSN

0741-3106

Type

jour

DOI

10.1109/LED.2006.889248

Filename

4068947