3-D Physical Electro-Thermal Modeling of Nanoscale Y2O3 Memristors for Synaptic Application

3-D Physical Electro-Thermal Modeling of Nanoscale Y2O3 Memristors for Synaptic Application

Here, we report the physical electro-thermal modeling of nanoscale Y 2 O 3 -based memristor devices. The simulation is carried out by the combined software package of COMSOL Multiphysics and MATLAB. The presented physical modeling is based on the minimization of free energy at an applied voltage. Th...

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Veröffentlicht in:IEEE transactions on electron devices 2022-06, Vol.69 (6), p.3124-3129
Hauptverfasser: Kumar, Sanjay, Gautam, Mohit Kumar, Gill, Gurpreet Singh, Mukherjee, Shaibal
Format: Artikel
Sprache:eng
Schlagworte:
Electric potential
Electro-thermal modeling
Free energy
Hysteresis loops
Iron
Mathematical models
memristor system
Memristors
Modelling
Nanoscale devices
Nanotechnology devices
Numerical models
Simulation
Switches
Switching
synaptic behavior
Thermal analysis
Thickness
Three dimensional models
Voltage
Yttrium oxide
Y₂O
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Zusammenfassung:Here, we report the physical electro-thermal modeling of nanoscale Y 2 O 3 -based memristor devices. The simulation is carried out by the combined software package of COMSOL Multiphysics and MATLAB. The presented physical modeling is based on the minimization of free energy at an applied voltage. The simulated results exhibit a stable pinched hysteresis loop in resistive switching (RS) response in multiple switching cycles. The RS responses show low values of coefficient of variability ( {C}_{V} ), i.e., 17.36% and 17.09% in SET and RESET voltages, respectively, during cycle-to-cycle variation. The impact of voltage ramp rate ( {V}_{RR} ) on the device characteristics such as switching response and synaptic plasticity behavior of the device is investigated. The simulated outcomes significantly depict the impact of oxide layer thickness on the switching voltages in the nanoscale device.
ISSN:0018-9383
1557-9646
DOI:10.1109/TED.2022.3166858