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Using intrinsic properties of quantum dots to provide additional security when uniquely identifying devices

Using intrinsic properties of quantum dots to provide additional security when uniquely identifying devices
Using intrinsic properties of quantum dots to provide additional security when uniquely identifying devices
Unique identification of optical devices is important for anti-counterfeiting. Physical unclonable functions (PUFs), which use random physical characteristics for authentication, are advantageous over existing optical solutions, such as holograms, due to the inherent asymmetry in their fabrication and reproduction complexity. However, whilst unique, PUFs are potentially vulnerable to replication and simulation. Here we introduce an additional benefit of a small modification to an established model of nanoparticle PUFs by using a second measurement parameter to verify their authenticity. A randomly deposited array of quantum dots is encapsulated in a transparent polymer, forming a tag. Photoluminescence is measured as a function of excitation power to assess uniqueness as well as the intrinsic nonlinear response of the quantum material. This captures a fingerprint, which is non-trivial to clone or simulate. To demonstrate this concept practically, we show that these tags can be read using an unmodified smartphone, with its built-in flash for excitation. This development over constellation-style optical PUFs paves the way for more secure, facile authentication of devices without requiring complex fabrication or characterisation techniques.
2045-2322
Fong, Matthew J.
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Woodhead, Christopher S.
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Abdelazim, Nema
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Abreu, Daniel C.
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Lamantia, Angelo
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Ball, Elliott M.
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Longmate, Kieran
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Howarth, David
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Robinson, Benjamin J.
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Speed, Phillip
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Young, Robert J.
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Fong, Matthew J.
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Woodhead, Christopher S.
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Abdelazim, Nema
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Abreu, Daniel C.
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Lamantia, Angelo
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Ball, Elliott M.
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Longmate, Kieran
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Howarth, David
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Robinson, Benjamin J.
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Speed, Phillip
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Young, Robert J.
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Fong, Matthew J., Woodhead, Christopher S., Abdelazim, Nema, Abreu, Daniel C., Lamantia, Angelo, Ball, Elliott M., Longmate, Kieran, Howarth, David, Robinson, Benjamin J., Speed, Phillip and Young, Robert J. (2022) Using intrinsic properties of quantum dots to provide additional security when uniquely identifying devices. Scientific Reports, 12 (1), [16919]. (doi:10.1038/s41598-022-20596-8).

Record type: Article

Abstract

Unique identification of optical devices is important for anti-counterfeiting. Physical unclonable functions (PUFs), which use random physical characteristics for authentication, are advantageous over existing optical solutions, such as holograms, due to the inherent asymmetry in their fabrication and reproduction complexity. However, whilst unique, PUFs are potentially vulnerable to replication and simulation. Here we introduce an additional benefit of a small modification to an established model of nanoparticle PUFs by using a second measurement parameter to verify their authenticity. A randomly deposited array of quantum dots is encapsulated in a transparent polymer, forming a tag. Photoluminescence is measured as a function of excitation power to assess uniqueness as well as the intrinsic nonlinear response of the quantum material. This captures a fingerprint, which is non-trivial to clone or simulate. To demonstrate this concept practically, we show that these tags can be read using an unmodified smartphone, with its built-in flash for excitation. This development over constellation-style optical PUFs paves the way for more secure, facile authentication of devices without requiring complex fabrication or characterisation techniques.

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s41598-022-20596-8 - Version of Record
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More information

Accepted/In Press date: 15 September 2022
Published date: 8 October 2022
Additional Information: Funding Information: The research is funded by Royal Society grant number UF160721, Air Force Office of Scientific Research grant number FA9550-19-1-0397 and Engineering and Physical Sciences Research Council, Grant No. EP/K50421X/1. Publisher Copyright: © 2022, The Author(s).

Identifiers

Local EPrints ID: 471442
URI: http://eprints.soton.ac.uk/id/eprint/471442
ISSN: 2045-2322
PURE UUID: 86b5dc76-380b-4b13-9e77-0a1b919bedcf

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Date deposited: 08 Nov 2022 18:26
Last modified: 16 Mar 2024 22:37

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Contributors

Author: Matthew J. Fong
Author: Christopher S. Woodhead
Author: Nema Abdelazim
Author: Daniel C. Abreu
Author: Angelo Lamantia
Author: Elliott M. Ball
Author: Kieran Longmate
Author: David Howarth
Author: Benjamin J. Robinson
Author: Phillip Speed
Author: Robert J. Young

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