Mie-Resonant Silicon Nanoparticles for Physically Unclonable Anti-Counterfeiting Labels

Kustov, Pavel; Petrova, E. A.; Nazarov, Mikhail; Gilmullin, Almaz; Sandomirskii, Martin; Ponkratova, Ekaterina; Yaroshenko, V. V.; Ageev, Eduard; Zuev, Dmitry

doi:10.1021/acsanm.2c01878

Cited by 12 publications

(6 citation statements)

References 46 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Even larger values can be easily achieved by increasing the number of pixels analyzed in Raman/PL maps or by functionalizing the hybrid Au-Si product with Raman-active molecules capable of providing additional bands for mapping . Raman and nonlinear PL signals are almost insensitive to the polarization of the pump radiation, facilitating a more reliable readout, in sharp contrast to recently proposed optical PUF labels based on resonant light scattering signals that are extremely sensitive to excitation conditions. − The PUF labels were produced by optimized drop-casting of the as-prepared Au-Si dispersions. The ability to concentrate produced MSs is very advantageous for SERS applications as well as for adequate characterization of the nanomaterial on the stage of synthesis optimization, especially when the droplet contains a small amount of analyzed nanoparticles.…”

Section: Discussionmentioning

confidence: 99%

Multigram-Scale Production of Hybrid Au-Si Nanomaterial by Laser Ablation in Liquid (LAL) for Temperature-Feedback Optical Nanosensing, Light-to-Heat Conversion, and Anticounterfeit Labeling

Gurbatov

Puzikov

Storozhenko

et al. 2023

ACS Appl. Mater. Interfaces

View full text Add to dashboard Cite

Recent progress in hybrid optical nanomaterials composed of dissimilar constituents permitted an improvement in the performance and functionality of novel devices developed for optoelectronics, catalysis, medical diagnostics, and sensing. However, the rational combination of contrasting materials such as noble metals and semiconductors within individual hybrid nanostructures via a ready-to-use and lithography-free fabrication approach is still a challenge. Here, we report on a two-step synthesis of hybrid Au-Si microspheres generated by laser ablation of silicon in isopropanol followed by laser irradiation of the produced Si nanoparticles in the presence of HAuCl 4 . Thermal reduction of [AuCl 4 ] − species to a metallic gold phase, along with its subsequent mixing with silicon under laser irradiation, creates a nanostructured material with a unique composition and morphology, as revealed by electron microscopy, tomography, and elemental analysis. A combination of basic plasmonic and nanophotonic materials such as gold and silicon within a single microsphere allows for efficient light-to-heat conversion, as well as single-particle SERS sensing with temperature-feedback modality and expanded functionality. Moreover, the characteristic Raman signal and hot-electron-induced nonlinear photoluminescence coexisting within the novel Au-Si hybrids, as well as the commonly criticized randomness of the nanomaterials prepared by laser ablation in liquid, were proved to be useful for the realization of anticounterfeiting labels based on a physically unclonable function approach.

show abstract

Section: Discussionmentioning

confidence: 99%

Multigram-Scale Production of Hybrid Au-Si Nanomaterial by Laser Ablation in Liquid (LAL) for Temperature-Feedback Optical Nanosensing, Light-to-Heat Conversion, and Anticounterfeit Labeling

Gurbatov

Puzikov

Storozhenko

et al. 2023

ACS Appl. Mater. Interfaces

View full text Add to dashboard Cite

show abstract

“…The crucial issue of this approach is the production of high-quality inks, in which Si NPs with a uniform size and shape are dispersed without agglomeration. Si NP inks satisfying these requirements had been hard to be produced by conventional processes such as plasma synthesis, − chemical vapor deposition, , laser ablation, ,,− and mechanical milling. , In previous work, ,,− we developed a process to produce suspensions of almost perfectly spherical Si NPs [Si nanospheres (Si NSs)] with very narrow size distributions. The suspension exhibited size-dependent vivid structural color due to the Mie resonance. ,, By mixing the suspension with an optically transparent binder such as polyvinylpyrrolidone, we produced the structural color inks and demonstrated coloration of a base material such as a PET film by painting …”

Section: Introductionmentioning

confidence: 99%

Monolayer of Mie-Resonant Silicon Nanospheres for Structural Coloration

Tanaka,

Hotta,

Hinamoto

et al. 2024

ACS Appl. Nano Mater.

View full text Add to dashboard Cite

Structural coloration of a monolayer of Mieresonant silicon (Si) nanospheres (NSs) produced by a solutionbased process is studied. It is shown by simulation that a monolayer of hexagonal close-packed Si NSs exhibits sizedependent structural color with a peak reflectance of ∼50%. The peak reflectance can be increased to over 90% by introducing spaces between the Si NSs. The high reflectance despite the small coverage is due to the very high scattering efficiency of Mieresonant Si NSs. Monolayers of densely packed Si NSs are produced from Si NS suspensions by the Langmuir−Blodgett method. The monolayers exhibit size-dependent structural color with a peak reflectance of 30−50%. The color is very insensitive to the viewing angle, and the angle dependence of the reflectance spectra is very small. The peak reflectance is increased by increasing the distance between the NSs by partially oxidizing the layers. The results demonstrate that iridescence-free structural coloration of a substance is possible by a layer of Si NSs much thinner than the monolayer, i.e., by sparsely scattered Si NSs.

show abstract

“…In theory, the secret keys of the PUF methods are almost impossible to copy. A challenge receives a response, which is called a challenge–response pair (CRP) of PUF. , CRPs are encoded and recorded in a database for verification and decryption. Searching a huge database for a CRP to verify is time-consuming and laborious.…”

Section: Introductionmentioning

confidence: 99%

Physically Unclonable Holographic Encryption and Anticounterfeiting Based on the Light Propagation of Complex Medium and Fluorescent Labels

Xu,

Feng,

Xie

et al. 2024

ACS Appl. Mater. Interfaces

View full text Add to dashboard Cite

Physically unclonable function (PUF) methods have high security, but their wide application is limited by complex encoding, large database, advanced external characterization equipment, and complicated comparative authentication. Therefore, we creatively propose the physically unclonable holographic encryption and anticounterfeiting based on the light propagation of complex medium and fluorescent labels. As far as we know, this is the first holographic encryption and anticounterfeiting method with a fluorescence physically unclonable property. The proposed method reduces the above requirements of traditional PUF methods and significantly reduces the cost. The angle-multiplexed PUF fluorescent label is the physical secret key. The information is encrypted as computer-generated holograms (CGH). Many physical parameters in the system are used as the parameter secret keys. The Diffie−Hellman key exchange algorithm is improved to transfer parameter secret keys. A variety of complex medium hologram generation methods are proposed and compared. The effectiveness, security, and robustness of the method are studied and analyzed. Finally, a graphical user interface (GUI) is designed for the convenience of users. The advantages of this method include lower PUF encoding complexity, effective reduction of the database size, lower requirements for characterization equipment, and direct use of decrypted information without complicated comparative authentication to reduce misjudgment. It is believed that the method proposed in this paper will pave the way for the popularization and application of PUF-based anticounterfeiting and encryption methods.

show abstract

Mie-Resonant Silicon Nanoparticles for Physically Unclonable Anti-Counterfeiting Labels

Cited by 12 publications

References 46 publications

Multigram-Scale Production of Hybrid Au-Si Nanomaterial by Laser Ablation in Liquid (LAL) for Temperature-Feedback Optical Nanosensing, Light-to-Heat Conversion, and Anticounterfeit Labeling

Multigram-Scale Production of Hybrid Au-Si Nanomaterial by Laser Ablation in Liquid (LAL) for Temperature-Feedback Optical Nanosensing, Light-to-Heat Conversion, and Anticounterfeit Labeling

Monolayer of Mie-Resonant Silicon Nanospheres for Structural Coloration

Physically Unclonable Holographic Encryption and Anticounterfeiting Based on the Light Propagation of Complex Medium and Fluorescent Labels

Contact Info

Product

Resources

About