Thermodynamic origin of nonvolatility in resistive memory

Jingxian Li; Anirudh Appachar; Sabrina L. Peczonczyk; Elisa T. Harrison; Anton V. Ievlev; Ryan Hood; Dongjae Shin; Sangmin Yoo; Brianna Roest; Kai Sun; Karsten Beckmann; Olya Popova; Tony Chiang; William S. Wahby; Robin B. Jacobs-Godrim; Matthew J. Marinella; Petro Maksymovych; John T. Heron; Nathaniel Cady; Wei D. Lu; Suhas Kumar; A. Alec Talin; Wenhao Sun; Yiyang Li

doi:10.1016/j.matt.2024.07.018

Thermodynamic origin of nonvolatility in resistive memory

Jingxian Li, Anirudh Appachar, Sabrina L. Peczonczyk, Elisa T. Harrison, Anton V. Ievlev, Ryan Hood, Dongjae Shin, Sangmin Yoo, Brianna Roest, Kai Sun, Karsten Beckmann, Olya Popova, Tony Chiang, William S. Wahby, Robin B. Jacobs-Godrim, Matthew J. Marinella, Petro Maksymovych, John T. Heron, Nathaniel Cady, Wei D. LuSuhas Kumar, A. Alec Talin, Wenhao Sun, Yiyang Li

Research output: Contribution to journal › Article › peer-review

7 Scopus citations

Abstract

Electronic switches based on the migration of high-density point defects, or memristors, are poised to revolutionize post-digital electronics. Despite significant research, key mechanisms for filament formation and oxygen transport remain unresolved, hindering our ability to predict and design device properties. For example, experiments have achieved 10 orders of magnitude longer retention times than predicted by current models. Here, using electrical measurements, scanning probe microscopy, and first-principles calculations on tantalum oxide memristors, we reveal that the formation and stability of conductive filaments crucially depend on the thermodynamic stability of the amorphous oxygen-rich and oxygen-poor compounds, which undergo composition phase separation. Including the previously neglected effects of this amorphous phase separation reconciles unexplained discrepancies in retention and enables predictive design of key performance indicators such as retention stability. This result emphasizes non-ideal thermodynamic interactions as key design criteria in post-digital devices with defect densities substantially exceeding those of today's covalent semiconductors.

Original language	English (US)
Pages (from-to)	3970-3993
Number of pages	24
Journal	Matter
Volume	7
Issue number	11
DOIs	https://doi.org/10.1016/j.matt.2024.07.018
State	Published - Nov 6 2024
Externally published	Yes

Keywords

MAP 3: Understanding
amorphous
memristor
oxygen diffusion
phase separation
phase-field model
retention

ASJC Scopus subject areas

General Materials Science

Access to Document

10.1016/j.matt.2024.07.018

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Li, J., Appachar, A., Peczonczyk, S. L., Harrison, E. T., Ievlev, A. V., Hood, R., Shin, D., Yoo, S., Roest, B., Sun, K., Beckmann, K., Popova, O., Chiang, T., Wahby, W. S., Jacobs-Godrim, R. B., Marinella, M. J., Maksymovych, P., Heron, J. T., Cady, N., ... Li, Y. (2024). Thermodynamic origin of nonvolatility in resistive memory. Matter, 7(11), 3970-3993. https://doi.org/10.1016/j.matt.2024.07.018

Li, J, Appachar, A, Peczonczyk, SL, Harrison, ET, Ievlev, AV, Hood, R, Shin, D, Yoo, S, Roest, B, Sun, K, Beckmann, K, Popova, O, Chiang, T, Wahby, WS, Jacobs-Godrim, RB, Marinella, MJ, Maksymovych, P, Heron, JT, Cady, N, Lu, WD, Kumar, S, Talin, AA, Sun, W & Li, Y 2024, 'Thermodynamic origin of nonvolatility in resistive memory', Matter, vol. 7, no. 11, pp. 3970-3993. https://doi.org/10.1016/j.matt.2024.07.018

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abstract = "Electronic switches based on the migration of high-density point defects, or memristors, are poised to revolutionize post-digital electronics. Despite significant research, key mechanisms for filament formation and oxygen transport remain unresolved, hindering our ability to predict and design device properties. For example, experiments have achieved 10 orders of magnitude longer retention times than predicted by current models. Here, using electrical measurements, scanning probe microscopy, and first-principles calculations on tantalum oxide memristors, we reveal that the formation and stability of conductive filaments crucially depend on the thermodynamic stability of the amorphous oxygen-rich and oxygen-poor compounds, which undergo composition phase separation. Including the previously neglected effects of this amorphous phase separation reconciles unexplained discrepancies in retention and enables predictive design of key performance indicators such as retention stability. This result emphasizes non-ideal thermodynamic interactions as key design criteria in post-digital devices with defect densities substantially exceeding those of today's covalent semiconductors.",

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AU - Li, Jingxian

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AU - Ievlev, Anton V.

AU - Hood, Ryan

AU - Shin, Dongjae

AU - Yoo, Sangmin

AU - Roest, Brianna

AU - Sun, Kai

AU - Beckmann, Karsten

AU - Popova, Olya

AU - Chiang, Tony

AU - Wahby, William S.

AU - Jacobs-Godrim, Robin B.

AU - Marinella, Matthew J.

AU - Maksymovych, Petro

AU - Heron, John T.

AU - Cady, Nathaniel

AU - Lu, Wei D.

AU - Kumar, Suhas

AU - Talin, A. Alec

AU - Sun, Wenhao

AU - Li, Yiyang

PY - 2024/11/6

Y1 - 2024/11/6

N2 - Electronic switches based on the migration of high-density point defects, or memristors, are poised to revolutionize post-digital electronics. Despite significant research, key mechanisms for filament formation and oxygen transport remain unresolved, hindering our ability to predict and design device properties. For example, experiments have achieved 10 orders of magnitude longer retention times than predicted by current models. Here, using electrical measurements, scanning probe microscopy, and first-principles calculations on tantalum oxide memristors, we reveal that the formation and stability of conductive filaments crucially depend on the thermodynamic stability of the amorphous oxygen-rich and oxygen-poor compounds, which undergo composition phase separation. Including the previously neglected effects of this amorphous phase separation reconciles unexplained discrepancies in retention and enables predictive design of key performance indicators such as retention stability. This result emphasizes non-ideal thermodynamic interactions as key design criteria in post-digital devices with defect densities substantially exceeding those of today's covalent semiconductors.

AB - Electronic switches based on the migration of high-density point defects, or memristors, are poised to revolutionize post-digital electronics. Despite significant research, key mechanisms for filament formation and oxygen transport remain unresolved, hindering our ability to predict and design device properties. For example, experiments have achieved 10 orders of magnitude longer retention times than predicted by current models. Here, using electrical measurements, scanning probe microscopy, and first-principles calculations on tantalum oxide memristors, we reveal that the formation and stability of conductive filaments crucially depend on the thermodynamic stability of the amorphous oxygen-rich and oxygen-poor compounds, which undergo composition phase separation. Including the previously neglected effects of this amorphous phase separation reconciles unexplained discrepancies in retention and enables predictive design of key performance indicators such as retention stability. This result emphasizes non-ideal thermodynamic interactions as key design criteria in post-digital devices with defect densities substantially exceeding those of today's covalent semiconductors.

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Thermodynamic origin of nonvolatility in resistive memory

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Keywords

ASJC Scopus subject areas

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