Physical Understanding of Program Injection and Consumption in Ultra-Scaled SiN Split-Gate Memories

Author

Masoero, L. ; Molas, G. ; Marca, V. Della ; Gély, M. ; Cueto, O. ; Colonna, J.P. ; De Luca, A. ; Brianceau, P. ; Charpin, C. ; Lafond, D. ; Delaye, V. ; Aussenac, F. ; Carabasse, C. ; Pauliac, S. ; Comboroure, C. ; Boivin, P. ; Ghibaudo, G. ; Deleonibus,

Author_Institution

LETI, CEA, Grenoble, France

fYear

2012

fDate

20-23 May 2012

Firstpage

1

Lastpage

4

Abstract

In this work, a detailed study of the physical mechanisms governing the Source Side Injection programming in ultra-scaled (down to 20nm) SiN split-gate memories is presented. Experimental measurements coupled to static and dynamic TCAD simulations are shown. In particular, we claim that adjusting the select gate voltage in moderate inversion allows for the optimization of the compromise between high electron injection and limited consumption. Then, we show that scaling the dimensions of the select gate can induce a higher consumption, while scaling the memory gate leads to lower programming energy (<;1nJ) due to higher injection efficiency, suitable for low power applications.

Keywords

memory architecture; semiconductor storage; silicon compounds; technology CAD (electronics); SiN; dynamic TCAD simulations; gate voltage; high electron injection; low power applications; physical mechanisms; physical understanding; program injection; programming energy; source side injection programming; static TCAD simulations; ultra-scaled SiN split-gate memories; Current measurement; Electric fields; Logic gates; Memory management; Programming; Split gate flash memory cells; Transistors;

fLanguage

English

Publisher

ieee

Conference_Titel

Memory Workshop (IMW), 2012 4th IEEE International

Conference_Location

Milan

Print_ISBN

978-1-4673-1079-6

Type

conf

DOI

10.1109/IMW.2012.6213686

Filename

6213686