Modeling the effects of different forming conditions on RRAM conductive filament stability

Author

Butcher, B. ; Bersuker, Gennadi ; Vandelli, Luca ; Padovani, A. ; Larcher, Luca ; Kalantarian, A. ; Geer, R. ; Gilmer, D.C.

Author_Institution

SEMATECH, Albany, NY, USA

fYear

2013

fDate

26-29 May 2013

Firstpage

52

Lastpage

55

Abstract

In order to identify the factors controlling the filament characteristics, we perform physics-based simulations of the inherently stochastic and difficult-to-control forming process using a statistical Monte-Carlo method to model the Hf-O bond-breakage, oxygen ion diffusion and vacancy-oxygen recombination. Simulation results well reproduce the experimental trends observed for the conductivity of the post-forming low resistance state under different forming conditions. It is shown that the distribution of the oxygen ions in the surrounding oxide during forming as well as local filament temperature and electrical field all affect the filament stability.

Keywords

Monte Carlo methods; chemical interdiffusion; electric field effects; ion recombination; random-access storage; vacancies (crystal); Hf-O bond-breakage; RRAM conductive filament stability; difficult-to-control forming process; electrical field; local filament temperature; oxygen ion diffusion; oxygen ions; physics-based simulations; statistical Monte-Carlo method; stochastic forming conditions; vacancy-oxygen recombination; Conductivity; Geometry; Hafnium compounds; Integrated circuits; Ions; Resistance; Temperature distribution; Hafnium; HfO2; HfO2−x; HfOx; Oxide; RRAM; ReRAM; device physics; forming; oxygen vacancies; resistive switching memory;

fLanguage

English

Publisher

ieee

Conference_Titel

Memory Workshop (IMW), 2013 5th IEEE International

Conference_Location

Monterey, CA

Print_ISBN

978-1-4673-6168-2

Type

conf

DOI

10.1109/IMW.2013.6582096

Filename

6582096