Hotspot generation for unique identification with nanomaterials

Hotspot generation for unique identification with nanomaterials

Abstract Nanoscale variations in the structure and composition of an object are an enticing basis for verifying its identity, due to the physical complexity of attempting to reproduce such a system. The biggest practical challenge for nanoscale authentication lies in producing a system that can be a...

Full description

Bibliographic Details
Main Authors: Nema M. Abdelazim, Matthew J. Fong, Thomas McGrath, Christopher S. Woodhead, Furat Al-Saymari, Ibrahim E. Bagci, Alex T. Jones, Xintai Wang, Robert J. Young
Format: Article
Language:English
Published: Nature Publishing Group 2021-01-01
Series:Scientific Reports
Online Access:https://doi.org/10.1038/s41598-020-79644-w
id doaj-29e0b687890f44f3b3691451d17b759b
record_format Article
spelling doaj-29e0b687890f44f3b3691451d17b759b2021-01-17T12:31:14ZengNature Publishing GroupScientific Reports2045-23222021-01-011111710.1038/s41598-020-79644-wHotspot generation for unique identification with nanomaterialsNema M. Abdelazim0Matthew J. Fong1Thomas McGrath2Christopher S. Woodhead3Furat Al-Saymari4Ibrahim E. Bagci5Alex T. Jones6Xintai Wang7Robert J. Young8Department of Physics, Lancaster UniversityDepartment of Physics, Lancaster UniversityDepartment of Physics, Lancaster UniversityDepartment of Physics, Lancaster UniversityDepartment of Physics, Lancaster UniversitySchool of Computing and Communications, Lancaster UniversityDepartment of Physics, Lancaster UniversityDepartment of Physics, Lancaster UniversityDepartment of Physics, Lancaster UniversityAbstract Nanoscale variations in the structure and composition of an object are an enticing basis for verifying its identity, due to the physical complexity of attempting to reproduce such a system. The biggest practical challenge for nanoscale authentication lies in producing a system that can be assessed with a facile measurement. Here, a system is presented in which InP/ZnS quantum dots (QDs) are randomly distributed on a surface of an aluminium-coated substrate with gold nanoparticles (Au NPs). Variations in the local arrangement of the QDs and NPs is shown to lead to interactions between them, which can suppress or enhance fluorescence from the QDs. This position-dependent interaction can be mapped, allowing intensity, emission dynamics, and/or wavelength variations to be used to uniquely identify a specific sample at the nanoscale with a far-field optical measurement. This demonstration could pave the way to producing robust anti-counterfeiting devices.https://doi.org/10.1038/s41598-020-79644-w
collection DOAJ
language English
format Article
sources DOAJ
author Nema M. Abdelazim
Matthew J. Fong
Thomas McGrath
Christopher S. Woodhead
Furat Al-Saymari
Ibrahim E. Bagci
Alex T. Jones
Xintai Wang
Robert J. Young
spellingShingle Nema M. Abdelazim
Matthew J. Fong
Thomas McGrath
Christopher S. Woodhead
Furat Al-Saymari
Ibrahim E. Bagci
Alex T. Jones
Xintai Wang
Robert J. Young
Hotspot generation for unique identification with nanomaterials
Scientific Reports
author_facet Nema M. Abdelazim
Matthew J. Fong
Thomas McGrath
Christopher S. Woodhead
Furat Al-Saymari
Ibrahim E. Bagci
Alex T. Jones
Xintai Wang
Robert J. Young
author_sort Nema M. Abdelazim
title Hotspot generation for unique identification with nanomaterials
title_short Hotspot generation for unique identification with nanomaterials
title_full Hotspot generation for unique identification with nanomaterials
title_fullStr Hotspot generation for unique identification with nanomaterials
title_full_unstemmed Hotspot generation for unique identification with nanomaterials
title_sort hotspot generation for unique identification with nanomaterials
publisher Nature Publishing Group
series Scientific Reports
issn 2045-2322
publishDate 2021-01-01
description Abstract Nanoscale variations in the structure and composition of an object are an enticing basis for verifying its identity, due to the physical complexity of attempting to reproduce such a system. The biggest practical challenge for nanoscale authentication lies in producing a system that can be assessed with a facile measurement. Here, a system is presented in which InP/ZnS quantum dots (QDs) are randomly distributed on a surface of an aluminium-coated substrate with gold nanoparticles (Au NPs). Variations in the local arrangement of the QDs and NPs is shown to lead to interactions between them, which can suppress or enhance fluorescence from the QDs. This position-dependent interaction can be mapped, allowing intensity, emission dynamics, and/or wavelength variations to be used to uniquely identify a specific sample at the nanoscale with a far-field optical measurement. This demonstration could pave the way to producing robust anti-counterfeiting devices.
url https://doi.org/10.1038/s41598-020-79644-w
work_keys_str_mv AT nemamabdelazim hotspotgenerationforuniqueidentificationwithnanomaterials
AT matthewjfong hotspotgenerationforuniqueidentificationwithnanomaterials
AT thomasmcgrath hotspotgenerationforuniqueidentificationwithnanomaterials
AT christopherswoodhead hotspotgenerationforuniqueidentificationwithnanomaterials
AT furatalsaymari hotspotgenerationforuniqueidentificationwithnanomaterials
AT ibrahimebagci hotspotgenerationforuniqueidentificationwithnanomaterials
AT alextjones hotspotgenerationforuniqueidentificationwithnanomaterials
AT xintaiwang hotspotgenerationforuniqueidentificationwithnanomaterials
AT robertjyoung hotspotgenerationforuniqueidentificationwithnanomaterials
_version_ 1724334735773138944

Similar Items