Conductive-filament switching analysis and self-accelerated thermal dissolution model for reset in NiO-based RRAM
2007 IEEE International Electron Devices Meeting, 2007•ieeexplore.ieee.org
This work presents detailed characterization and modeling of the reset operation in resistive-
switching memories based on metal oxides. Our experimental results confirm previous
observations that reset is controlled by Joule heating, providing an insight on the electrical
and thermal parameters of the conductive filament (CF) in the low resistance state. The
characterization of such parameters allows to model the CF rupture responsible for reset
switching. Our model explains the switching by self-accelerated dissolution of the CF, and …
switching memories based on metal oxides. Our experimental results confirm previous
observations that reset is controlled by Joule heating, providing an insight on the electrical
and thermal parameters of the conductive filament (CF) in the low resistance state. The
characterization of such parameters allows to model the CF rupture responsible for reset
switching. Our model explains the switching by self-accelerated dissolution of the CF, and …
This work presents detailed characterization and modeling of the reset operation in resistive-switching memories based on metal oxides. Our experimental results confirm previous observations that reset is controlled by Joule heating, providing an insight on the electrical and thermal parameters of the conductive filament (CF) in the low resistance state. The characterization of such parameters allows to model the CF rupture responsible for reset switching. Our model explains the switching by self-accelerated dissolution of the CF, and can quantitatively account for reset and data-retention experiments. The scaling of programming current is finally investigated by means of reduction of CF cross-section.
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