Disordered photonic structures are promising for the realization of physical unclonable functions-physical objects that can overcome the limitations of conventional digital security and can enable cryptographic protocols immune against attacks by future quantum computers. The physical configuration of traditional physical unclonable functions is either fixed or can only be permanently modified, allowing one token per device and limiting their practicality. Here we overcome this limitation by creating reconfigurable structures made by light-transformable polymers in which the physical structure of the unclonable function can be reconfigured reversibly. Our approach allows the simultaneous coexistence of multiple physical unclonable functions within one device. The physical transformation is done all-optically in a reversible and spatially controlled fashion, allowing the generation of more complex keys. At the same time, as a set of switchable individual physical unclonable functions, it enables the authentication of multiple clients and allows for the practical implementations of quantum secure authentication and nonlinear generators of cryptographic keys.Employing light-transformable polymers, multiple physical unclonable functions are demonstrated within a single device with all-optical reversible reconfigurability. Such devices may enable quantum secure authentication and nonlinear cryptographic key generation applications.

All-optical multilevel physical unclonable functions / Nocentini, Sara; Rührmair, Ulrich; Barni, Mauro; Wiersma, Diederik S.; Riboli, Francesco. - In: NATURE MATERIALS. - ISSN 1476-1122. - STAMPA. - 23:(2024), pp. 369-376. [10.1038/s41563-023-01734-7]

All-optical multilevel physical unclonable functions

Barni, Mauro
Membro del Collaboration Group
;
Wiersma, Diederik S.
Membro del Collaboration Group
;
Riboli, Francesco
Membro del Collaboration Group
2024

Abstract

Disordered photonic structures are promising for the realization of physical unclonable functions-physical objects that can overcome the limitations of conventional digital security and can enable cryptographic protocols immune against attacks by future quantum computers. The physical configuration of traditional physical unclonable functions is either fixed or can only be permanently modified, allowing one token per device and limiting their practicality. Here we overcome this limitation by creating reconfigurable structures made by light-transformable polymers in which the physical structure of the unclonable function can be reconfigured reversibly. Our approach allows the simultaneous coexistence of multiple physical unclonable functions within one device. The physical transformation is done all-optically in a reversible and spatially controlled fashion, allowing the generation of more complex keys. At the same time, as a set of switchable individual physical unclonable functions, it enables the authentication of multiple clients and allows for the practical implementations of quantum secure authentication and nonlinear generators of cryptographic keys.Employing light-transformable polymers, multiple physical unclonable functions are demonstrated within a single device with all-optical reversible reconfigurability. Such devices may enable quantum secure authentication and nonlinear cryptographic key generation applications.
2024
23
369
376
Nocentini, Sara; Rührmair, Ulrich; Barni, Mauro; Wiersma, Diederik S.; Riboli, Francesco
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Utilizza questo identificatore per citare o creare un link a questa risorsa: https://hdl.handle.net/2158/1356451
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