Title :
Experimentally demonstrated filament-based switching mechanism for Al/CuxO/Cu memristive devices
Author :
McDonald, N.R. ; Bishop, S.M. ; Cady, Nathaniel C.
Author_Institution :
Inf. Directorate, Air Force Res. Lab. (AFRL), Rome, NY, USA
Abstract :
Al/CuxO/Cu memristive devices created via a plasma oxidation step have previously demonstrated complete nonpolar switching behavior [1]. An additional material contamination control measure resulted in improved uniformity of I-V curve behavior but necessitated an initial forming step in most devices. The operation voltages were irrespective of switching style and top electrode (TE) size. The high resistance state resistance increased with decreasing TE size; the low resistance state resistance remained invariant. Lateral switching of memristive device pairs unambiguously indicated filament-based device switching. A voltage-driven CuxO filament composition modulation switching mechanism is suggested instead of the popular Joule heating RESET mechanism.
Keywords :
aluminium; contamination; copper; copper compounds; electrodes; memristors; oxidation; Al-CuxO-Cu; I-V curve behavior; Joule heating reset mechanism; TE size; high resistance state resistance; lateral switching; low resistance state resistance; material contamination control measure; memristive device pairs; nonpolar switching behavior; plasma oxidation step; top electrode size; unambiguously indicated filament-based device switching; voltage-driven filament composition modulation switching mechanism; Films; Immune system; Oxidation; Plasmas; Resistance; Switches;
Conference_Titel :
Integrated Reliability Workshop Final Report (IRW), 2012 IEEE International
Conference_Location :
South Lake Tahoe, CA
Print_ISBN :
978-1-4673-2749-7
DOI :
10.1109/IIRW.2012.6468954
