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Ultra‐secure optical encryption based on tightly focused perfect optical vortex beams

Qingshuai Yang, Zijian Xie, Mengrui Zhang, Xu Ouyang, Yi Xu, Yaoyu Cao, Sicong Wang, Linwei Zhu, Xiangping Li

2022Nanophotonics83 citationsDOIOpen Access PDF

Abstract

Light's orbital angular momentum (OAM) with inherent mode orthogonality has been suggested as a new way to the optical encryption. However, the dependence of annular intensity profiles on the topological charge complicates nanoscale light-matter interactions and hampers the ultra-secure encryption application. In this paper, we demonstrate ultra-secure image encryption by tightly focusing perfect optical vortex (POV) beams with controllable annular intensity profiles and OAM states. A simple scheme composed of single spatial light modulator to implement Fourier transform of an ideal Bessel mode with both amplitude and phase modulations is proposed to generate radius-controllable POV in tightly focused beams. Such focused POV beams with identical intensity profiles but varied local OAM density are applied to disorder-coupled gold nanorod aggregates to selectively excite electromagnetic hot spots for encoding information through photothermal deformation. As such, ultra-secure image encryption in OAM states of POV beams in combination with different polarizations can be achieved. Our results lay the ground for diverse nanophotonic applications harnessing the OAM division of POV beams.

Topics & Concepts

EncryptionOpticsOptical vortexStructured lightSpatial light modulatorPhysicsAngular momentumNanophotonicsBeam (structure)Computer scienceQuantum mechanicsOperating systemOrbital Angular Momentum in OpticsPlasmonic and Surface Plasmon ResearchGold and Silver Nanoparticles Synthesis and Applications
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