Author :
Govoreanu, B. ; Ajaykumar, Arjun ; Lipowicz, H. ; Chen, Ying-Yu ; Liu, J.-C. ; Degraeve, Robin ; Zhang, Leiqi ; Clima, S. ; Goux, L. ; Radu, Iuliana P. ; Fantini, Andrea ; Raghavan, N. ; Kar, G.-S. ; Kim, Wonhee ; Redolfi, A. ; Wouters, D.J. ; Altimime, L
Abstract :
We report on the performance and reliability of the Hf/HfO2 RRAM cell with Ultra-Thin Oxide (UTO-RRAM). We show that cells with an oxide thickness of 3 nm have basic performance (including speed, switching voltages, and the on/off window) similar to that of the cells with reference oxide (5-10 nm thickness), while their operation requires a forming step at a voltage of only about 1.5 V for a 40 nm size. This performance can be further optimized by tuning the cap layer thickness. We also demonstrate endurance of at least 108 cy and observe failure modes similar to the reference cells. Endurance optimization needs to take into account, next to the stack structure and pulse characteristics, the target on/off states. UTO-RRAM retention is strongly temperature-activated, with a median cell extrapolating at 125°C/10 yr. Furthermore, we analyze in detail the on-state loss and show how emergence of tail bits relates to the strength (initial level) of the state.
Keywords :
extrapolation; hafnium; hafnium compounds; integrated circuit reliability; random-access storage; Hf-HfO2; RRAM cell; UTO-RRAM; cap layer thickness; failure modes; median cell extrapolation; reference cells; reference oxide; reliability; size 3 nm; ultrathin oxide; ultrathin-based RRAM; Hafnium compounds; Reliability; Resistance; Switches; Temperature distribution; Voltage control; HfO2-based RRAM; Resistive RAM (RRAM); data loss; ultra-thin oxide RRAM (UTO-RRAM);
