Open AccessModeling of a quantized current and gate field-effect in gated three-terminal Cu2-αS electrochemical memristors
Author(s) -
Y. Zhang,
Nurunnahar Islam Mou,
P.-L. Pai,
Massood TabibAzar
Publication year - 2015
Publication title -
aip advances
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.421
H-Index - 58
ISSN - 2158-3226
DOI - 10.1063/1.4913372
Subject(s) - memristor , voltage , reset (finance) , materials science , electrical conductor , terminal (telecommunication) , thermal conduction , optoelectronics , logic gate , and gate , electrical engineering , nanotechnology , computer science , engineering , telecommunications , financial economics , economics , composite material
Memristors exhibit very sharp off-to-on transitions with a large on/off resistance ratio. These remarkable characteristics coupled with their long retention time and very simple device geometry make them nearly ideal for three-terminal devices where the gate voltage can change their on/off voltages and/or simply turn them off, eliminating the need for bipolar operations. In this paper, we propose a cation migration-based computational model to explain the quantized current conduction and the gate field-effect in Cu2-αS memristors. Having tree-shaped conductive filaments inside a memristor is the reason for the quantized current conduction effect. Applying a gate voltage causes a deformation of the conductive filaments and thus controls the SET and the RESET process of the device
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