Neuromorphic learning with Mott insulator NiO

Zhen Zhang; Sandip Mondal; Subhasish Mandal; Jason M. Allred; Neda Alsadat Aghamiri; Alireza Fali; Zhan Zhang; Hua Zhou; Hui Cao; Fanny Rodolakis; Jessica L. McChesney; Qi Wang; Yifei Sun; Yohannes Abate; Kaushik Roy; Karin M. Rabe; Shriram Ramanathan

doi:10.1073/pnas.2017239118

Neuromorphic learning with Mott insulator NiO

Zhen Zhang
, Sandip Mondal
, Subhasish Mandal
, Jason M. Allred
, Neda Alsadat Aghamiri
, Alireza Fali
, Zhan Zhang
, Hua Zhou
, Hui Cao
, Fanny Rodolakis
, Jessica L. McChesney
, Qi Wang
, Yifei Sun
, Yohannes Abate
, Kaushik Roy
, Karin M. Rabe
, Shriram Ramanathan

Purdue University
Rutgers - The State University of New Jersey, New Brunswick
University of Georgia
United States Department of Energy
Argonne National Laboratory

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

30 Scopus citations

Abstract

Habituation and sensitization (nonassociative learning) are among themost fundamental forms of learning and memory behavior present in organisms that enable adaptation and learning in dynamic environments. Emulating such features of intelligence found in nature in the solid state can serve as inspiration for algorithmic simulations in artificial neural networks and potential use in neuromorphic computing. Here, we demonstrate nonassociative learning with a prototypical Mott insulator, nickel oxide (NiO), under a variety of external stimuli at and above room temperature. Similar to biological species such as Aplysia, habituation and sensitization of NiO possess time-dependent plasticity relying on both strength and time interval between stimuli. A combination of experimental approaches and first-principles calculations reveals that such learning behavior of NiO results from dynamic modulation of its defect and electronic structure. An artificial neural network model inspired by such nonassociative learning is simulated to show advantages for an unsupervised clustering task in accuracy and reducing catastrophic interference, which could help mitigate the stability-plasticity dilemma. Mott insulators can therefore serve as building blocks to examine learning behavior noted in biology and inspire new learning algorithms for artificial intelligence.

Original language	English
Article number	e2017239118
Journal	Proceedings of the National Academy of Sciences of the United States of America
Volume	118
Issue number	39
DOIs	https://doi.org/10.1073/pnas.2017239118
State	Published - 28 Sep 2021
Externally published	Yes

Keywords

Mott insulator
Neuromorphic learning
Transition metal oxides

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10.1073/pnas.2017239118

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Zhang, Z., Mondal, S., Mandal, S., Allred, J. M., Aghamiri, N. A., Fali, A., Zhang, Z., Zhou, H., Cao, H., Rodolakis, F., McChesney, J. L., Wang, Q., Sun, Y., Abate, Y., Roy, K., Rabe, K. M., & Ramanathan, S. (2021). Neuromorphic learning with Mott insulator NiO. Proceedings of the National Academy of Sciences of the United States of America, 118(39), Article e2017239118. https://doi.org/10.1073/pnas.2017239118

@article{ed1c09de770d4eca9a5ded096133d9c3,

title = "Neuromorphic learning with Mott insulator NiO",

abstract = "Habituation and sensitization (nonassociative learning) are among themost fundamental forms of learning and memory behavior present in organisms that enable adaptation and learning in dynamic environments. Emulating such features of intelligence found in nature in the solid state can serve as inspiration for algorithmic simulations in artificial neural networks and potential use in neuromorphic computing. Here, we demonstrate nonassociative learning with a prototypical Mott insulator, nickel oxide (NiO), under a variety of external stimuli at and above room temperature. Similar to biological species such as Aplysia, habituation and sensitization of NiO possess time-dependent plasticity relying on both strength and time interval between stimuli. A combination of experimental approaches and first-principles calculations reveals that such learning behavior of NiO results from dynamic modulation of its defect and electronic structure. An artificial neural network model inspired by such nonassociative learning is simulated to show advantages for an unsupervised clustering task in accuracy and reducing catastrophic interference, which could help mitigate the stability-plasticity dilemma. Mott insulators can therefore serve as building blocks to examine learning behavior noted in biology and inspire new learning algorithms for artificial intelligence.",

keywords = "Mott insulator, Neuromorphic learning, Transition metal oxides",

author = "Zhen Zhang and Sandip Mondal and Subhasish Mandal and Allred, \{Jason M.\} and Aghamiri, \{Neda Alsadat\} and Alireza Fali and Zhan Zhang and Hua Zhou and Hui Cao and Fanny Rodolakis and McChesney, \{Jessica L.\} and Qi Wang and Yifei Sun and Yohannes Abate and Kaushik Roy and Rabe, \{Karin M.\} and Shriram Ramanathan",

year = "2021",

month = sep,

day = "28",

doi = "10.1073/pnas.2017239118",

language = "英语",

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journal = "Proceedings of the National Academy of Sciences of the United States of America",

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number = "39",

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Zhang, Z, Mondal, S, Mandal, S, Allred, JM, Aghamiri, NA, Fali, A, Zhang, Z, Zhou, H, Cao, H, Rodolakis, F, McChesney, JL, Wang, Q, Sun, Y, Abate, Y, Roy, K, Rabe, KM & Ramanathan, S 2021, 'Neuromorphic learning with Mott insulator NiO', Proceedings of the National Academy of Sciences of the United States of America, vol. 118, no. 39, e2017239118. https://doi.org/10.1073/pnas.2017239118

TY - JOUR

T1 - Neuromorphic learning with Mott insulator NiO

AU - Zhang, Zhen

AU - Mondal, Sandip

AU - Mandal, Subhasish

AU - Allred, Jason M.

AU - Aghamiri, Neda Alsadat

AU - Fali, Alireza

AU - Zhang, Zhan

AU - Zhou, Hua

AU - Cao, Hui

AU - Rodolakis, Fanny

AU - McChesney, Jessica L.

AU - Wang, Qi

AU - Sun, Yifei

AU - Abate, Yohannes

AU - Roy, Kaushik

AU - Rabe, Karin M.

AU - Ramanathan, Shriram

PY - 2021/9/28

Y1 - 2021/9/28

N2 - Habituation and sensitization (nonassociative learning) are among themost fundamental forms of learning and memory behavior present in organisms that enable adaptation and learning in dynamic environments. Emulating such features of intelligence found in nature in the solid state can serve as inspiration for algorithmic simulations in artificial neural networks and potential use in neuromorphic computing. Here, we demonstrate nonassociative learning with a prototypical Mott insulator, nickel oxide (NiO), under a variety of external stimuli at and above room temperature. Similar to biological species such as Aplysia, habituation and sensitization of NiO possess time-dependent plasticity relying on both strength and time interval between stimuli. A combination of experimental approaches and first-principles calculations reveals that such learning behavior of NiO results from dynamic modulation of its defect and electronic structure. An artificial neural network model inspired by such nonassociative learning is simulated to show advantages for an unsupervised clustering task in accuracy and reducing catastrophic interference, which could help mitigate the stability-plasticity dilemma. Mott insulators can therefore serve as building blocks to examine learning behavior noted in biology and inspire new learning algorithms for artificial intelligence.

AB - Habituation and sensitization (nonassociative learning) are among themost fundamental forms of learning and memory behavior present in organisms that enable adaptation and learning in dynamic environments. Emulating such features of intelligence found in nature in the solid state can serve as inspiration for algorithmic simulations in artificial neural networks and potential use in neuromorphic computing. Here, we demonstrate nonassociative learning with a prototypical Mott insulator, nickel oxide (NiO), under a variety of external stimuli at and above room temperature. Similar to biological species such as Aplysia, habituation and sensitization of NiO possess time-dependent plasticity relying on both strength and time interval between stimuli. A combination of experimental approaches and first-principles calculations reveals that such learning behavior of NiO results from dynamic modulation of its defect and electronic structure. An artificial neural network model inspired by such nonassociative learning is simulated to show advantages for an unsupervised clustering task in accuracy and reducing catastrophic interference, which could help mitigate the stability-plasticity dilemma. Mott insulators can therefore serve as building blocks to examine learning behavior noted in biology and inspire new learning algorithms for artificial intelligence.

KW - Mott insulator

KW - Neuromorphic learning

KW - Transition metal oxides

UR - https://www.scopus.com/pages/publications/85116020994

U2 - 10.1073/pnas.2017239118

DO - 10.1073/pnas.2017239118

M3 - 文章

C2 - 34531299

AN - SCOPUS:85116020994

SN - 0027-8424

VL - 118

JO - Proceedings of the National Academy of Sciences of the United States of America

JF - Proceedings of the National Academy of Sciences of the United States of America

IS - 39

M1 - e2017239118

ER -

Neuromorphic learning with Mott insulator NiO

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Keywords

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