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Single-contact, four-terminal microelectromechanical relay for efficient digital logic

Single-contact, four-terminal microelectromechanical relay for efficient digital logic
Single-contact, four-terminal microelectromechanical relay for efficient digital logic
Nano and microelectromechanical relays can be used in lieu of transistors to build digital integrated circuits that can operate with zero leakage current at high operating temperatures and radiation levels. Four-terminal (4-T) relays facilitate efficient logic circuits with greatly reduced device counts compared to three-terminal (3-T) relay implementations. Existing 4-T relays, however, require two moving contacts to simultaneously land on two stationary electrodes, which can adversely impact reliability, or have complex out-of-plane fabrication methods that can reduce yield and increase cost while having poor scalability. In this work an in-plane four-terminal relay with a single moving contact is demonstrated for the first time, through successful fabrication and characterization of prototypes with a critical dimension of 1.5 µm. Body biasing is shown to reduce the pull-in voltage of this 4-T relay compared to a 3-T relay with the same architecture and footprint. The potential of the 4-T relay to build efficient logic circuits is demonstrated by fabricating and characterizing a 1-to-2 demultiplexer (DEMUX) circuit using only two devices, a saving of eight devices over a 3-T relay implementation.
body biasing, demultiplexers, four-terminal relay, microelectromechanical technology, nanocrystalline graphite, nanoelectromechanical technology, relay-based circuits
Reynolds, Jamie Dean
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Rana, Sunil
16726f81-3e09-45e4-b07b-944e7679e8ca
Worsey, Elliot
154c4c60-37aa-4ecf-b7e5-b4feea5b51a0
Tang, Qi
0edc7420-a764-4d31-a3f4-83f99acd89fd
Kulsreshath, Mukesh K.
6f87916a-421f-49b9-afe4-7368fa5ef8a4
Chong, Harold
795aa67f-29e5-480f-b1bc-9bd5c0d558e1
Pamunuwa, Dinesh
cf57fb7f-b05a-48d0-a9ef-2aca5f411cc3
Reynolds, Jamie Dean
96faa744-02ee-458c-8e48-953ea9e54afe
Rana, Sunil
16726f81-3e09-45e4-b07b-944e7679e8ca
Worsey, Elliot
154c4c60-37aa-4ecf-b7e5-b4feea5b51a0
Tang, Qi
0edc7420-a764-4d31-a3f4-83f99acd89fd
Kulsreshath, Mukesh K.
6f87916a-421f-49b9-afe4-7368fa5ef8a4
Chong, Harold
795aa67f-29e5-480f-b1bc-9bd5c0d558e1
Pamunuwa, Dinesh
cf57fb7f-b05a-48d0-a9ef-2aca5f411cc3

Reynolds, Jamie Dean, Rana, Sunil, Worsey, Elliot, Tang, Qi, Kulsreshath, Mukesh K., Chong, Harold and Pamunuwa, Dinesh (2022) Single-contact, four-terminal microelectromechanical relay for efficient digital logic. Advanced Electronic Materials, [202200584]. (doi:10.1002/aelm.202200584).

Record type: Article

Abstract

Nano and microelectromechanical relays can be used in lieu of transistors to build digital integrated circuits that can operate with zero leakage current at high operating temperatures and radiation levels. Four-terminal (4-T) relays facilitate efficient logic circuits with greatly reduced device counts compared to three-terminal (3-T) relay implementations. Existing 4-T relays, however, require two moving contacts to simultaneously land on two stationary electrodes, which can adversely impact reliability, or have complex out-of-plane fabrication methods that can reduce yield and increase cost while having poor scalability. In this work an in-plane four-terminal relay with a single moving contact is demonstrated for the first time, through successful fabrication and characterization of prototypes with a critical dimension of 1.5 µm. Body biasing is shown to reduce the pull-in voltage of this 4-T relay compared to a 3-T relay with the same architecture and footprint. The potential of the 4-T relay to build efficient logic circuits is demonstrated by fabricating and characterizing a 1-to-2 demultiplexer (DEMUX) circuit using only two devices, a saving of eight devices over a 3-T relay implementation.

Text
Adv Elect Materials - 2022 - Reynolds - Single‐Contact Four‐Terminal Microelectromechanical Relay for Efficient Digital - Version of Record
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e-pub ahead of print date: 6 September 2022
Published date: 6 September 2022
Additional Information: Funding Information: This research received funding from the Royal Academy of Engineering Senior Research Fellowship (RCSRF1920‐9‐53) awarded to D.P. and the EU H2020 research and innovation programme under grant agreement No. 871740 (ZeroAMP). This work was also supported by the University of Bristol Cleanroom Facility through UK EPSRC grant QuPIC (EP/N015126/1) and the Nanofabrication Centre at the University of Southampton through EPSRC Platform Grant EP/N013247/1. Publisher Copyright: © 2022 The Authors. Advanced Electronic Materials published by Wiley-VCH GmbH.
Keywords: body biasing, demultiplexers, four-terminal relay, microelectromechanical technology, nanocrystalline graphite, nanoelectromechanical technology, relay-based circuits

Identifiers

Local EPrints ID: 470286
URI: http://eprints.soton.ac.uk/id/eprint/470286
PURE UUID: 953b7dde-e168-4bc4-b3dc-715b413a67cf
ORCID for Jamie Dean Reynolds: ORCID iD orcid.org/0000-0002-0072-0134
ORCID for Harold Chong: ORCID iD orcid.org/0000-0002-7110-5761

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Date deposited: 05 Oct 2022 16:50
Last modified: 17 Mar 2024 03:12

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Contributors

Author: Jamie Dean Reynolds ORCID iD
Author: Sunil Rana
Author: Elliot Worsey
Author: Qi Tang
Author: Mukesh K. Kulsreshath
Author: Harold Chong ORCID iD
Author: Dinesh Pamunuwa

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