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Home / Information Technologies through Topotactic Phase Transitions
Information Technologies through Topotactic Phase Transitions
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Information Technologies through Topotactic Phase Transitions

Venkata Raveendra Nallagatla
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Redox memristive devices, driven by oxygen migration, offer promise for future data storage. Brownmillerite structures, like SrCoO2.5 and SrFeO2.5, enable reversible topotactic phase transitions, optimizing redox and resistive switching in memristive devices. Challenges in SrCoO2.5 thin films are addressed with atomically flat SrFeO2.5, showcasing improved performance. Epitaxial growth on [111]-oriented SrTiO3 enhances controlled oxygen ion migration, achieving high endurance and fast switching. X-ray absorption spectromicroscopy reveals the redox-based phase transition's role, and (111)-oriented devices exhibit localized transitions. SrFeO2.5 (111) devices demonstrate promising synaptic memory functionality, contributing to a neural network model with 90% accuracy in hand-written number identification.

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MORE INFO
Format
Paperback
Publisher
LAP Lambert Academic Publishing
Date
19 March 2024
Pages
128
ISBN
9786207472369

Redox memristive devices, driven by oxygen migration, offer promise for future data storage. Brownmillerite structures, like SrCoO2.5 and SrFeO2.5, enable reversible topotactic phase transitions, optimizing redox and resistive switching in memristive devices. Challenges in SrCoO2.5 thin films are addressed with atomically flat SrFeO2.5, showcasing improved performance. Epitaxial growth on [111]-oriented SrTiO3 enhances controlled oxygen ion migration, achieving high endurance and fast switching. X-ray absorption spectromicroscopy reveals the redox-based phase transition's role, and (111)-oriented devices exhibit localized transitions. SrFeO2.5 (111) devices demonstrate promising synaptic memory functionality, contributing to a neural network model with 90% accuracy in hand-written number identification.

Read More
Format
Paperback
Publisher
LAP Lambert Academic Publishing
Date
19 March 2024
Pages
128
ISBN
9786207472369

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