Title :
Investigation of switching mechanism in forming-free multi-level resistive memories with atomic layer deposited HfTiOx nanolaminate
Author :
Chakrabarti, B. ; Miranda, E. ; Vogel, Eric M.
Author_Institution :
Dept. of Mater. Sci. & Eng., Univ. of Texas at Dallas, Richardson, TX, USA
Abstract :
Forming-free resistive memories (RRAM) have recently attracted significant attention as the forming process requires high voltage and can lead to low yield because of current overshoot [1-2]. We have recently demonstrated forming-free switching with multi-level operation in TiN/HfTiOx/TiN resistive memories [3]. However, a fundamental understanding of the switching mechanisms is lacking. Recently the Quantum Point Contact model (QPC) has been applied to analyze switching behavior of conductive filament based resistive memories [4-5]. Investigation of multi-level switching in HfTiOx-based resistive memories using the QPC model has not been attempted previously. In this work we have investigated the multi-level conduction mechanism of forming-free HfTiOx RRAMs using the QPC model. We demonstrate that the model can successfully describe the entire dynamic range of multi-level switching for the HfTiOx RRAMs.
Keywords :
atomic layer deposition; hafnium compounds; integrated circuit modelling; random-access storage; titanium compounds; HfTiOx; QPC model; atomic layer deposited nanolaminate; conductive filament-based resistive memories; current overshoot; forming process; forming-free RRAM; forming-free multilevel resistive memories; forming-free switching; multilevel conduction mechanism; multilevel switching; quantum point contact model; switching mechanism; Educational institutions; Hafnium compounds; Materials; Memory management; Resistance; Switches; Tin;
Conference_Titel :
Device Research Conference (DRC), 2014 72nd Annual
Conference_Location :
Santa Barbara, CA
Print_ISBN :
978-1-4799-5405-6
DOI :
10.1109/DRC.2014.6872330
