Title :
RTN insight to filamentary instability and disturb immunity in ultra-low power switching HfOx and AlOx RRAM
Author :
Raghavan, N. ; Degraeve, Robin ; Goux, L. ; Fantini, Andrea ; Wouters, D.J. ; Groeseneken, Guido ; Jurczak, Malgorzata
Author_Institution :
Emerging Memories Group, IMEC, Heverlee, Belgium
Abstract :
Random telegraph noise (RTN) is a critical reliability metric impacting the memory state during read operation in resistive switching memory. In this study, we develop a time-efficient (a) slow ramped stress technique for quantitative RTN assessment to determine the disturb voltage (VDIST) for oxygen vacancy perturbations in the filament. The technique is used to (b) identify the best regimes of operation for RRAM with superior RTN robustness and (c) investigate dielectric material properties that govern stability of the filament using the thermochemical bond breaking / ionic migration transport model as the basis. The proposed method is exemplified comparing HfOx and AlOx stacks. Shape and size of filament in high resistance state (HRS) has a big impact on RTN.
Keywords :
aluminium compounds; burst noise; dielectric materials; hafnium compounds; low-power electronics; random-access storage; AlOx; AlOx RRAM; HRS; HfOx; HfOx RRAM; RTN robustness; critical reliability metric; dielectric material property; disturb immunity; filamentary instability; high resistance state; ionic migration transport model; oxygen vacancy perturbation; quantitative RTN assessment; random telegraph noise; resistive switching memory; thermochemical bond breaking; time-efficient slow ramped stress technique; ultra-low power switching; Electron traps; Hafnium oxide; Market research; Robustness; Shape; Switches;
Conference_Titel :
VLSI Technology (VLSIT), 2013 Symposium on
Conference_Location :
Kyoto
Print_ISBN :
978-1-4673-5226-0
