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Autores principales: Hua, Erbing, Spyrou, Theofilos, Ahmadi, Majid, Syed, Abdul Momin, Xun, Hanzhi, Braic, Laurentiu, van der Veer, Ewout, Elatab, Nazek, Gebregiorgis, Anteneh, Gaydadjiev, Georgi, Noheda, Beatriz, Hamdioui, Said, Ishihara, Ryoichi, Abunahla, Heba
Formato: Preprint
Publicado: 2025
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Acceso en línea:https://arxiv.org/abs/2505.22789
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author Hua, Erbing
Spyrou, Theofilos
Ahmadi, Majid
Syed, Abdul Momin
Xun, Hanzhi
Braic, Laurentiu
van der Veer, Ewout
Elatab, Nazek
Gebregiorgis, Anteneh
Gaydadjiev, Georgi
Noheda, Beatriz
Hamdioui, Said
Ishihara, Ryoichi
Abunahla, Heba
author_facet Hua, Erbing
Spyrou, Theofilos
Ahmadi, Majid
Syed, Abdul Momin
Xun, Hanzhi
Braic, Laurentiu
van der Veer, Ewout
Elatab, Nazek
Gebregiorgis, Anteneh
Gaydadjiev, Georgi
Noheda, Beatriz
Hamdioui, Said
Ishihara, Ryoichi
Abunahla, Heba
contents Memristor technology shows great promise for energy-efficient computing, yet it grapples with challenges like resistance drift and inherent variability. For filamentary Resistive RAM (ReRAM), one of the most investigated types of memristive devices, the expensive electroforming step required to create conductive pathways results in increased power and area overheads and reduced endurance. In this study, we present novel HfO2-based forming-free ReRAM devices, PdNeuRAM, that operate at low voltages, support multi-bit functionality, and display reduced variability. Through a deep understanding and comprehensive material characterization, we discover the key process that allows this unique behavior: a Pd-O-Hf configuration that capitalizes on Pd innate affinity for integrating into HfO2. This structure actively facilitates charge redistribution at room temperature, effectively eliminating the need for electroforming. Moreover, the fabricated ReRAM device provides tunable resistance states for dense memory and reduces programming and reading energy by 43% and 73%, respectively, using spiking neural networks (SNN). This study reveals novel mechanistic insights and delineates a strategic roadmap for the realization of power-efficient and cost-effective ReRAM devices.
format Preprint
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publishDate 2025
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spellingShingle PdNeuRAM: forming-free, multi-bit Pd/HfO2 ReRAM for energy-efficient neuromorphic computing
Hua, Erbing
Spyrou, Theofilos
Ahmadi, Majid
Syed, Abdul Momin
Xun, Hanzhi
Braic, Laurentiu
van der Veer, Ewout
Elatab, Nazek
Gebregiorgis, Anteneh
Gaydadjiev, Georgi
Noheda, Beatriz
Hamdioui, Said
Ishihara, Ryoichi
Abunahla, Heba
Materials Science
Image and Video Processing
Memristor technology shows great promise for energy-efficient computing, yet it grapples with challenges like resistance drift and inherent variability. For filamentary Resistive RAM (ReRAM), one of the most investigated types of memristive devices, the expensive electroforming step required to create conductive pathways results in increased power and area overheads and reduced endurance. In this study, we present novel HfO2-based forming-free ReRAM devices, PdNeuRAM, that operate at low voltages, support multi-bit functionality, and display reduced variability. Through a deep understanding and comprehensive material characterization, we discover the key process that allows this unique behavior: a Pd-O-Hf configuration that capitalizes on Pd innate affinity for integrating into HfO2. This structure actively facilitates charge redistribution at room temperature, effectively eliminating the need for electroforming. Moreover, the fabricated ReRAM device provides tunable resistance states for dense memory and reduces programming and reading energy by 43% and 73%, respectively, using spiking neural networks (SNN). This study reveals novel mechanistic insights and delineates a strategic roadmap for the realization of power-efficient and cost-effective ReRAM devices.
title PdNeuRAM: forming-free, multi-bit Pd/HfO2 ReRAM for energy-efficient neuromorphic computing
topic Materials Science
Image and Video Processing
url https://arxiv.org/abs/2505.22789