A versatile multifaceted resistive switching memory activated by light and ion irradiation in poly (3-octylthiophene)-zinc oxide hybrids

The resistive switching memory behavior activated by simulated solar light and swift heavy ion irradiation in poly (3-octylthiophene)-zinc oxide hybrid devices are reported. The current-voltage characteristics show the appearance of a remarkable hysteresis in reverse bias and a considerable in a for...

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Bibliographic Details
Published in:Organic electronics 2020-12, Vol.87, p.105932, Article 105932
Main Authors: Singh, Jitendra, Singh, R.G., Gautam, Subodh K., Gupta, Himanshi, Singh, Fouran
Format: Article
Language:English
Subjects:
Conducting filament formation
Resistive switching memory
Simulated solar light
Swift heavy ions
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Summary:The resistive switching memory behavior activated by simulated solar light and swift heavy ion irradiation in poly (3-octylthiophene)-zinc oxide hybrid devices are reported. The current-voltage characteristics show the appearance of a remarkable hysteresis in reverse bias and a considerable in a forward bias upon illumination by simulated solar light results in memory behavior. Ion irradiation exhibits strong enhancement of the memory behavior under both dark and light illuminations. Thus, the memory response is activated and/or enhanced upon illumination by light and irradiation along with the cyclic endurance of the devices. This is attributed due to the formation of well built-in conducting filament pathways through the trapping of injected and photo-generated charges via irradiation-induced electrically active defect and trap states and well explained by a schematic energy band diagram. The defect density induced upon ion irradiation works as a dominant factor and thus the tailoring of the interfacial properties of the hybrid devices leads to the strong strengthening of memory formations. Thus, the hybrid devices can be activated and/or enhanced by light and irradiation for potential fast resistive switching memory applications. [Display omitted] •Organic-inorganic hybrid based a versatile multifaceted resistive switching (RS) memory activated by light and ion irradiation.•RS memory with very high cyclic endurance of the devices.•The mechanism of activation is explained by formation of conducting filaments due to the ordering of the polymer and the transient charging of molecular chains.•Such low cost and simple devices have lots of potentials as non-volatile RSM and could be easily integrated in the existing silicon-based technology.
ISSN:1566-1199
1878-5530
DOI:10.1016/j.orgel.2020.105932