Title :
Nanoparticle floating gate flash memories
Author :
Banerjee, S. ; Kim, Dongkyu ; Kim, T. ; Weltzer, L. ; Liu, Y. ; Tang, S. ; Palard, M.
Author_Institution :
Microelectron. Res. Center, Texas Univ., Austin, TX, USA
Abstract :
This work presents the use of SiGe nanoparticle floating gates on high-k gate tunneling dielectrics, which, along with SiGe cold cathodes in the channel, are ways to enhance the low voltage/power operation of flash cells, improve the speed and charge retention. Control of dot sizes and spatial distributions may be improved by templated growth. Instead of an array of nanoparticles, it is also possible to use single quantum dots, and exploit Coulomb blockade and multi-level storage in single electron/few electron charge memories, but such devices are susceptible to background charges. It is possible to envision vertical cell structures in a cross-point array at the intersections of the wordlines and bitlines, which can result in an ideal 4F2 architecture.
Keywords :
Coulomb blockade; Ge-Si alloys; dielectric thin films; flash memories; low-power electronics; nanoparticles; semiconductor materials; semiconductor quantum dots; single electron devices; tunnelling; Coulomb blockade; SiGe; channel SiGe cold cathodes; charge retention; cross-point array; dot size control; dot spatial distribution; few electron charge memories; flash cell speed improvement; high-k gate tunneling dielectrics; low power operation; low voltage operation; multilevel storage; nanoparticle floating gate flash memories; single electron charge memories; single quantum dots; templated growth; vertical cell structures; wordline/bitline intersections; Cathodes; Electrons; Flash memory; Germanium silicon alloys; High K dielectric materials; High-K gate dielectrics; Low voltage; Nonvolatile memory; Silicon germanium; Tunneling;
Conference_Titel :
Device Research Conference, 2004. 62nd DRC. Conference Digest [Includes 'Late News Papers' volume]
Print_ISBN :
0-7803-8284-6
DOI :
10.1109/DRC.2004.1367759
