N-state random switching based on quantum tunnelling

Ramón Bernardo Gavito; Fernando Jiménez Urbanos; Jonathan Roberts; James Sexton; Benjamin Astbury; Hamzah Shokeir; Thomas McGrath; Yasir J. Noori; Christopher S. Woodhead; Mohamed Missous; Utz Roedig; Robert J. Young

doi:10.1117/12.2273298

N-state random switching based on quantum tunnelling

Ramón Bernardo Gavito, Fernando Jiménez Urbanos, Jonathan Roberts, James Sexton, Benjamin Astbury, Hamzah Shokeir, Thomas McGrath, Yasir J. Noori, Christopher S. Woodhead, Mohamed Missous, Utz Roedig, Robert J. Young

The University of Manchester

Research output: Chapter in Book/Conference proceeding › Conference contribution › peer-review

Abstract

In this work, we show how the hysteretic behaviour of resonant tunnelling diodes (RTDs) can be exploited for new functionalities. In particular, the RTDs exhibit a stochastic 2-state switching mechanism that could be useful for random number generation and cryptographic applications. This behaviour can be scaled to N-bit switching, by connecting various RTDs in series. The InGaAs/AlAs RTDs used in our experiments display very sharp negative differential resistance (NDR) peaks at room temperature which show hysteresis cycles that, rather than having a fixed switching threshold, show a probability distribution about a central value. We propose to use this intrinsic uncertainty emerging from the quantum nature of the RTDs as a source of randomness. We show that a combination of two RTDs in series results in devices with three-state outputs and discuss the possibility of scaling to N-state devices by subsequent series connections of RTDs, which we demonstrate for the up to the 4-state case. In this work, we suggest using that the intrinsic uncertainty in the conduction paths of resonant tunnelling diodes can behave as a source of randomness that can be integrated into current electronics to produce on-chip true random number generators. The N-shaped I-V characteristic of RTDs results in a two-level random voltage output when driven with current pulse trains. Electrical characterisation and randomness testing of the devices was conducted in order to determine the validity of the true randomness assumption. Based on the results obtained for the single RTD case, we suggest the possibility of using multi-well devices to generate N-state random switching devices for their use in random number generation or multi-valued logic devices.

Original language	English
Title of host publication	Nanoengineering
Subtitle of host publication	Fabrication, Properties, Optics, and Devices XIV
Editors	Eva M. Campo, Louay A. Eldada, Elizabeth A. Dobisz
Publisher	SPIE
Volume	10354
ISBN (Electronic)	9781510611658
DOIs	https://doi.org/10.1117/12.2273298
Publication status	Published - 1 Jan 2017
Event	Nanoengineering: Fabrication, Properties, Optics, and Devices XIV 2017 - San Diego, United States Duration: 9 Aug 2017 → 10 Aug 2017

Conference

Conference	Nanoengineering: Fabrication, Properties, Optics, and Devices XIV 2017
Country/Territory	United States
City	San Diego
Period	9/08/17 → 10/08/17

Keywords

multi-valued logic
quantum well
random number generation
Resonant tunneling diode

Access to Document

10.1117/12.2273298

Cite this

Bernardo Gavito, R., Jiménez Urbanos, F., Roberts, J., Sexton, J., Astbury, B., Shokeir, H., McGrath, T., Noori, Y. J., Woodhead, C. S., Missous, M., Roedig, U., & Young, R. J. (2017). N-state random switching based on quantum tunnelling. In E. M. Campo, L. A. Eldada, & E. A. Dobisz (Eds.), Nanoengineering: Fabrication, Properties, Optics, and Devices XIV (Vol. 10354). Article 103541T SPIE. https://doi.org/10.1117/12.2273298

@inproceedings{00283412e2704fdeb43f7b2777e4009e,

title = "N-state random switching based on quantum tunnelling",

abstract = "In this work, we show how the hysteretic behaviour of resonant tunnelling diodes (RTDs) can be exploited for new functionalities. In particular, the RTDs exhibit a stochastic 2-state switching mechanism that could be useful for random number generation and cryptographic applications. This behaviour can be scaled to N-bit switching, by connecting various RTDs in series. The InGaAs/AlAs RTDs used in our experiments display very sharp negative differential resistance (NDR) peaks at room temperature which show hysteresis cycles that, rather than having a fixed switching threshold, show a probability distribution about a central value. We propose to use this intrinsic uncertainty emerging from the quantum nature of the RTDs as a source of randomness. We show that a combination of two RTDs in series results in devices with three-state outputs and discuss the possibility of scaling to N-state devices by subsequent series connections of RTDs, which we demonstrate for the up to the 4-state case. In this work, we suggest using that the intrinsic uncertainty in the conduction paths of resonant tunnelling diodes can behave as a source of randomness that can be integrated into current electronics to produce on-chip true random number generators. The N-shaped I-V characteristic of RTDs results in a two-level random voltage output when driven with current pulse trains. Electrical characterisation and randomness testing of the devices was conducted in order to determine the validity of the true randomness assumption. Based on the results obtained for the single RTD case, we suggest the possibility of using multi-well devices to generate N-state random switching devices for their use in random number generation or multi-valued logic devices.",

keywords = "multi-valued logic, quantum well, random number generation, Resonant tunneling diode",

author = "\{Bernardo Gavito\}, Ram{\'o}n and \{Jim{\'e}nez Urbanos\}, Fernando and Jonathan Roberts and James Sexton and Benjamin Astbury and Hamzah Shokeir and Thomas McGrath and Noori, \{Yasir J.\} and Woodhead, \{Christopher S.\} and Mohamed Missous and Utz Roedig and Young, \{Robert J.\}",

year = "2017",

month = jan,

day = "1",

doi = "10.1117/12.2273298",

language = "English",

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booktitle = "Nanoengineering",

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note = "Nanoengineering: Fabrication, Properties, Optics, and Devices XIV 2017 ; Conference date: 09-08-2017 Through 10-08-2017",

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Bernardo Gavito, R, Jiménez Urbanos, F, Roberts, J, Sexton, J, Astbury, B, Shokeir, H, McGrath, T, Noori, YJ, Woodhead, CS, Missous, M, Roedig, U & Young, RJ 2017, N-state random switching based on quantum tunnelling. in EM Campo, LA Eldada & EA Dobisz (eds), Nanoengineering: Fabrication, Properties, Optics, and Devices XIV. vol. 10354, 103541T, SPIE, Nanoengineering: Fabrication, Properties, Optics, and Devices XIV 2017, San Diego, United States, 9/08/17. https://doi.org/10.1117/12.2273298

N-state random switching based on quantum tunnelling. / Bernardo Gavito, Ramón; Jiménez Urbanos, Fernando; Roberts, Jonathan et al.
Nanoengineering: Fabrication, Properties, Optics, and Devices XIV. ed. / Eva M. Campo; Louay A. Eldada; Elizabeth A. Dobisz. Vol. 10354 SPIE, 2017. 103541T.

Research output: Chapter in Book/Conference proceeding › Conference contribution › peer-review

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AU - Bernardo Gavito, Ramón

AU - Jiménez Urbanos, Fernando

AU - Roberts, Jonathan

AU - Sexton, James

AU - Astbury, Benjamin

AU - Shokeir, Hamzah

AU - McGrath, Thomas

AU - Noori, Yasir J.

AU - Woodhead, Christopher S.

AU - Missous, Mohamed

AU - Roedig, Utz

AU - Young, Robert J.

PY - 2017/1/1

Y1 - 2017/1/1

N2 - In this work, we show how the hysteretic behaviour of resonant tunnelling diodes (RTDs) can be exploited for new functionalities. In particular, the RTDs exhibit a stochastic 2-state switching mechanism that could be useful for random number generation and cryptographic applications. This behaviour can be scaled to N-bit switching, by connecting various RTDs in series. The InGaAs/AlAs RTDs used in our experiments display very sharp negative differential resistance (NDR) peaks at room temperature which show hysteresis cycles that, rather than having a fixed switching threshold, show a probability distribution about a central value. We propose to use this intrinsic uncertainty emerging from the quantum nature of the RTDs as a source of randomness. We show that a combination of two RTDs in series results in devices with three-state outputs and discuss the possibility of scaling to N-state devices by subsequent series connections of RTDs, which we demonstrate for the up to the 4-state case. In this work, we suggest using that the intrinsic uncertainty in the conduction paths of resonant tunnelling diodes can behave as a source of randomness that can be integrated into current electronics to produce on-chip true random number generators. The N-shaped I-V characteristic of RTDs results in a two-level random voltage output when driven with current pulse trains. Electrical characterisation and randomness testing of the devices was conducted in order to determine the validity of the true randomness assumption. Based on the results obtained for the single RTD case, we suggest the possibility of using multi-well devices to generate N-state random switching devices for their use in random number generation or multi-valued logic devices.

AB - In this work, we show how the hysteretic behaviour of resonant tunnelling diodes (RTDs) can be exploited for new functionalities. In particular, the RTDs exhibit a stochastic 2-state switching mechanism that could be useful for random number generation and cryptographic applications. This behaviour can be scaled to N-bit switching, by connecting various RTDs in series. The InGaAs/AlAs RTDs used in our experiments display very sharp negative differential resistance (NDR) peaks at room temperature which show hysteresis cycles that, rather than having a fixed switching threshold, show a probability distribution about a central value. We propose to use this intrinsic uncertainty emerging from the quantum nature of the RTDs as a source of randomness. We show that a combination of two RTDs in series results in devices with three-state outputs and discuss the possibility of scaling to N-state devices by subsequent series connections of RTDs, which we demonstrate for the up to the 4-state case. In this work, we suggest using that the intrinsic uncertainty in the conduction paths of resonant tunnelling diodes can behave as a source of randomness that can be integrated into current electronics to produce on-chip true random number generators. The N-shaped I-V characteristic of RTDs results in a two-level random voltage output when driven with current pulse trains. Electrical characterisation and randomness testing of the devices was conducted in order to determine the validity of the true randomness assumption. Based on the results obtained for the single RTD case, we suggest the possibility of using multi-well devices to generate N-state random switching devices for their use in random number generation or multi-valued logic devices.

KW - multi-valued logic

KW - quantum well

KW - random number generation

KW - Resonant tunneling diode

U2 - 10.1117/12.2273298

DO - 10.1117/12.2273298

M3 - Conference contribution

AN - SCOPUS:85033400414

VL - 10354

BT - Nanoengineering

A2 - Campo, Eva M.

A2 - Eldada, Louay A.

A2 - Dobisz, Elizabeth A.

PB - SPIE

T2 - Nanoengineering: Fabrication, Properties, Optics, and Devices XIV 2017

Y2 - 9 August 2017 through 10 August 2017

ER -

N-state random switching based on quantum tunnelling

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Keywords

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