Title :
Modeling of Quantized Conductance Effects in Electrochemical Metallization Cells
Author :
Tappertzhofen, Stefan ; Linn, Eike ; Menzel, Stephan ; Kenyon, Anthony J. ; Waser, Rainer ; Valov, Ilia
Author_Institution :
Dept. of Eng., Univ. of Cambridge, Cambridge, UK
Abstract :
The integration of microelectronics and information technology goes progressively on, and nonvolatile memory devices are now based on processes on the atomic scale. Thus, quantum size effects become an inevitable part of the modern devices. Here, we report on conductance quantization effects in electrochemical metallization cells at room temperature. We modified the extended memristor model for a SPICE simulation based on the experimental results for SiO2- and AgI-based ECM cells. Additionally, we present a 1-D kinetic Monte Carlo simulation model to account for quantum size effects. Our simulation models comprises the impact of the recently discovered nonequilibrium states on the stability of quantized conductance values and reproduces the stochastic nature of the resistance levels.
Keywords :
Monte Carlo methods; electrochemistry; integrated circuits; memristors; metallisation; resistive RAM; size effect; stochastic processes; 1D kinetic Monte Carlo simulation; AgI; AgI-based ECM cells; SPICE simulation; SiO2; SiO2-based ECM cells; conductance quantization effects; electrochemical metallization cells; extended memristor model; information technology; microelectronics; nonequilibrium states; nonvolatile memory devices; quantized conductance values; quantum size effects; resistance levels; stochastic nature; temperature 293 K to 298 K; Electrodes; Electronic countermeasures; Integrated circuit modeling; Quantization (signal); Radio frequency; Resistance; Switches; Modeling; modeling; non-equilibrium states; nonequilibrium states; quantized conductance; resistive switching;
Journal_Title :
Nanotechnology, IEEE Transactions on
DOI :
10.1109/TNANO.2015.2411774
