Charge disproportionate molecular redox for discrete memristive and memcapacitive switching

Sreetosh Goswami; Santi P. Rath; Damien Thompson; Svante Hedström; Meenakshi Annamalai; Rajib Pramanick; B. Robert Ilic; Soumya Sarkar; Sonu Hooda; Christian A. Nijhuis; Jens Martin; R. Stanley Williams; Sreebrata Goswami; T. Venkatesan

doi:10.1038/s41565-020-0653-1

Charge disproportionate molecular redox for discrete memristive and memcapacitive switching

Sreetosh Goswami
, Santi P. Rath
, Damien Thompson
, Svante Hedström
, Meenakshi Annamalai
, Rajib Pramanick
, B. Robert Ilic
, Soumya Sarkar
, Sonu Hooda
, Christian A. Nijhuis
, Jens Martin
, R. Stanley Williams
, Sreebrata Goswami
, T. Venkatesan

Department of Physics

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

Abstract

Electronic symmetry breaking by charge disproportionation results in multifaceted changes in the electronic, magnetic and optical properties of a material, triggering ferroelectricity, metal/insulator transition and colossal magnetoresistance. Yet, charge disproportionation lacks technological relevance because it occurs only under specific physical conditions of high or low temperature or high pressure. Here we demonstrate a voltage-triggered charge disproportionation in thin molecular films of a metal–organic complex occurring in ambient conditions. This provides a technologically relevant molecular route for simultaneous realization of a ternary memristor and a binary memcapacitor, scalable down to a device area of 60 nm². Supported by mathematical modelling, our results establish that multiple memristive states can be functionally non-volatile, yet discrete—a combination perceived as theoretically prohibited. Our device could be used as a binary or ternary memristor, a binary memcapacitor or both concomitantly, and unlike the existing ‘continuous state’ memristors, its discrete states are optimal for high-density, ultra-low-energy digital computing.

Original language	English
Pages (from-to)	380-389
Number of pages	10
Journal	Nature Nanotechnology
Volume	15
Issue number	5
DOIs	https://doi.org/10.1038/s41565-020-0653-1
Publication status	Published - 1 May 2020

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Goswami, S., Rath, S. P., Thompson, D., Hedström, S., Annamalai, M., Pramanick, R., Ilic, B. R., Sarkar, S., Hooda, S., Nijhuis, C. A., Martin, J., Williams, R. S., Goswami, S., & Venkatesan, T. (2020). Charge disproportionate molecular redox for discrete memristive and memcapacitive switching. Nature Nanotechnology, 15(5), 380-389. https://doi.org/10.1038/s41565-020-0653-1

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title = "Charge disproportionate molecular redox for discrete memristive and memcapacitive switching",

abstract = "Electronic symmetry breaking by charge disproportionation results in multifaceted changes in the electronic, magnetic and optical properties of a material, triggering ferroelectricity, metal/insulator transition and colossal magnetoresistance. Yet, charge disproportionation lacks technological relevance because it occurs only under specific physical conditions of high or low temperature or high pressure. Here we demonstrate a voltage-triggered charge disproportionation in thin molecular films of a metal–organic complex occurring in ambient conditions. This provides a technologically relevant molecular route for simultaneous realization of a ternary memristor and a binary memcapacitor, scalable down to a device area of 60 nm2. Supported by mathematical modelling, our results establish that multiple memristive states can be functionally non-volatile, yet discrete—a combination perceived as theoretically prohibited. Our device could be used as a binary or ternary memristor, a binary memcapacitor or both concomitantly, and unlike the existing {\textquoteleft}continuous state{\textquoteright} memristors, its discrete states are optimal for high-density, ultra-low-energy digital computing.",

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AU - Goswami, Sreetosh

AU - Rath, Santi P.

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AU - Hedström, Svante

AU - Annamalai, Meenakshi

AU - Pramanick, Rajib

AU - Ilic, B. Robert

AU - Sarkar, Soumya

AU - Hooda, Sonu

AU - Nijhuis, Christian A.

AU - Martin, Jens

AU - Williams, R. Stanley

AU - Goswami, Sreebrata

AU - Venkatesan, T.

PY - 2020/5/1

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N2 - Electronic symmetry breaking by charge disproportionation results in multifaceted changes in the electronic, magnetic and optical properties of a material, triggering ferroelectricity, metal/insulator transition and colossal magnetoresistance. Yet, charge disproportionation lacks technological relevance because it occurs only under specific physical conditions of high or low temperature or high pressure. Here we demonstrate a voltage-triggered charge disproportionation in thin molecular films of a metal–organic complex occurring in ambient conditions. This provides a technologically relevant molecular route for simultaneous realization of a ternary memristor and a binary memcapacitor, scalable down to a device area of 60 nm2. Supported by mathematical modelling, our results establish that multiple memristive states can be functionally non-volatile, yet discrete—a combination perceived as theoretically prohibited. Our device could be used as a binary or ternary memristor, a binary memcapacitor or both concomitantly, and unlike the existing ‘continuous state’ memristors, its discrete states are optimal for high-density, ultra-low-energy digital computing.

AB - Electronic symmetry breaking by charge disproportionation results in multifaceted changes in the electronic, magnetic and optical properties of a material, triggering ferroelectricity, metal/insulator transition and colossal magnetoresistance. Yet, charge disproportionation lacks technological relevance because it occurs only under specific physical conditions of high or low temperature or high pressure. Here we demonstrate a voltage-triggered charge disproportionation in thin molecular films of a metal–organic complex occurring in ambient conditions. This provides a technologically relevant molecular route for simultaneous realization of a ternary memristor and a binary memcapacitor, scalable down to a device area of 60 nm2. Supported by mathematical modelling, our results establish that multiple memristive states can be functionally non-volatile, yet discrete—a combination perceived as theoretically prohibited. Our device could be used as a binary or ternary memristor, a binary memcapacitor or both concomitantly, and unlike the existing ‘continuous state’ memristors, its discrete states are optimal for high-density, ultra-low-energy digital computing.

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Charge disproportionate molecular redox for discrete memristive and memcapacitive switching

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