Memristive State Equation for Bipolar Resistive Switching Devices Based on a Dynamic Balance Model and Its Equivalent Circuit Representation
A memory state equation consistent with a number of experimental observations is presented and discussed within the framework of Chua's memristive systems theory. The proposed equation describes the evolution of the memory state corresponding to a bipolar resistive switching device subject to a...
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| Published in | IEEE transactions on nanotechnology Vol. 19; pp. 837 - 840 |
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| Main Authors | , |
| Format | Journal Article |
| Language | English |
| Published |
New York
IEEE
2020
The Institute of Electrical and Electronics Engineers, Inc. (IEEE) |
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| Abstract | A memory state equation consistent with a number of experimental observations is presented and discussed within the framework of Chua's memristive systems theory. The proposed equation describes the evolution of the memory state corresponding to a bipolar resistive switching device subject to a variety of electrical stimuli. It is shown that the memory equation agrees with: i ) the characteristic switching time associated with the ion/vacancy hopping mechanism within the dielectric film, ii ) the SET/RESET voltage logarithmic dependence on the voltage sweep ramp rate, iii ) the hysteretic behavior of the remnant conductance for cycled input signals, iv ) the generation of self-similar conductance loops for arbitrary initial conditions, and v ) the collapse of the resistive window with the increment of the input signal frequency. It is also shown that the proposed equation admits a circuital representation suitable for circuit simulations. |
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| AbstractList | A memory state equation consistent with a number of experimental observations is presented and discussed within the framework of Chua's memristive systems theory. The proposed equation describes the evolution of the memory state corresponding to a bipolar resistive switching device subject to a variety of electrical stimuli. It is shown that the memory equation agrees with: i ) the characteristic switching time associated with the ion/vacancy hopping mechanism within the dielectric film, ii ) the SET/RESET voltage logarithmic dependence on the voltage sweep ramp rate, iii ) the hysteretic behavior of the remnant conductance for cycled input signals, iv ) the generation of self-similar conductance loops for arbitrary initial conditions, and v ) the collapse of the resistive window with the increment of the input signal frequency. It is also shown that the proposed equation admits a circuital representation suitable for circuit simulations. |
| Author | Miranda, Enrique Sune, Jordi |
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| SubjectTerms | Differential equations Electric potential Equations of state Equivalent circuits Initial conditions Integrated circuit modeling Mathematical model memory Memory devices Memristor Representations Resistance resistive switching Self-similarity Signal generation Switches Switching Switching circuits System theory Systems theory Voltage |
| Title | Memristive State Equation for Bipolar Resistive Switching Devices Based on a Dynamic Balance Model and Its Equivalent Circuit Representation |
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