Impact of crystallinity on coexistence of negative differential resistance (NDR) and write once read many (WORM) resistive switching memory in multiferroic BiFeO3 (BFO)

The materials exhibiting the negative differential resistance (NDR) and write once read many (WORM), simultaneously are potential candidates for electronic devices such as oscillators and permanent storage devices. Here in, we investigated the impact of crystallinity on coexistence of NDR and WORM r...

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Bibliographic Details
Published in:Applied physics. A, Materials science & processing Materials science & processing, 2023-02, Vol.129 (2), Article 116
Main Authors: Prakash, Chandra, Yadav, Ankit K., Dixit, Ambesh
Format: Article
Language:English
Subjects:
Amorphous materials
Applied physics
Bismuth ferrite
Characterization and Evaluation of Materials
Condensed Matter Physics
Copper
Crystallinity
Data storage
Electronic devices
Machines
Manufacturing
Materials science
Memory devices
Multiferroic materials
Nanotechnology
Optical and Electronic Materials
Physics
Physics and Astronomy
Power consumption
Power management
Processes
Substrates
Surfaces and Interfaces
Switching
Thin Films
Valleys
Weibull distribution
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Summary:The materials exhibiting the negative differential resistance (NDR) and write once read many (WORM), simultaneously are potential candidates for electronic devices such as oscillators and permanent storage devices. Here in, we investigated the impact of crystallinity on coexistence of NDR and WORM resistive switching on Cu(top contact)/BiFeO 3 (amorphous/crystalline) (BFO as active material)/FTO (bottom electrode) memory device. The multiferroic BiFeO 3 (BFO) active material is synthesized using a low-cost solution process on FTO substrates and thermal evaporation was used for deposing metal copper as the top contacts. The present device Cu/am-BFO/FTO showed the coexistence of WORM with high I on / I off ratio of ~ 10 3 and NDR with peak ( V p ) and valley (V v ) voltages ~  −  0.26 V and − 1.23 V, respectively. The power consumption is significantly low, ~ 66.94 µW in NDR region for am-BFO. The device with active crystalline material, i.e., Cu/c-BFO/FTO exhibits peak ( V p ) and valley ( V v ) voltages ~  −  1.22 V and − 1.40 V, respectively, and the power consumption is ~ 1.08 mW for devices based on crystalline BFO as an active material. The retention and endurance values are ~ 10 3  s and 10 3 cycles. The repeatability of the bipolar resistive switching of c-BFO is measured for 100 cycles, and relative cumulative Weibull distribution plots show the filament’s stability for both set and reset states. Thus, these results demonstrate the interplay between different switching characteristics in BFO, which can be tailored by manipulating the crystallinity of the active material.
ISSN:0947-8396
1432-0630
DOI:10.1007/s00339-022-06372-5