Laser Generation of Sub‐Micrometer Wrinkles in a Chalcogenide Glass Film as Physical Unclonable Functions

Martinez, Paloma; Papagiannouli, Irène; Descamps, D.; Petit, S.; Marthelot, Joël; Lévy, Anna; Fabre, B.; Dory, Jean‐Baptiste; Bernier, Nicolas; Raty, Jean‐Yves; Noé, Pierre; Gaudin, J.

doi:10.1002/adma.202003032

Cited by 24 publications

(33 citation statements)

References 29 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…However, the formation of fingerprints patterns observed by post‐experiment phase‐contrast microscopy (see ref. [40] and Figure , Supporting Information) leaves no doubt on the formation of a liquid layer for F ≥ 26 mJ cm −2 . The volume of melted material increases with time as the front of the liquid phase propagates thanks to thermal transport, and the shrinkage becomes large enough to be detected.…”

Section: Resultsmentioning

confidence: 99%

“…FDI results presented in Figure 1 clearly indicate a transition from the as‐deposited GeTe to another state upon laser excitation. Since post‐experiment nano‐beam electron diffraction analysis within the irradiated volume of the GeTe film reveals no sign of crystallization, [ 40 ] the final state is also an amorphous state, but distinct from the initial one as evidenced by the change of refractive index shown on the optical microscope pictures (Figure , Supporting Information). To identify the origin of the underlying process behind this transition, we conducted ab initio molecular dynamics (AIMD) simulations.…”

Section: Resultsmentioning

confidence: 99%

See 1 more Smart Citation

Sub‐Picosecond Non‐Equilibrium States in the Amorphous Phase of GeTe Phase‐Change Material Thin Films

et al. 2021

Self Cite

View full text Add to dashboard Cite

The sub‐picosecond response of amorphous germanium telluride thin film to a femtosecond laser excitation is investigated using frequency‐domain interferometry and ab initio molecular dynamics. The time‐resolved measurement of the surface dynamics reveals a shrinkage of the film with a dielectric properties’ response faster than 300 fs. The systematic ab initio molecular dynamics simulations in non‐equilibrium conditions allow the atomic configurations to be retrieved for ionic temperature from 300 to 1100 K and width of the electron distribution from 0.001 to 1.0 eV. Local order of the structures is characterized by in‐depth analysis of the angle distribution, phonon modes, and pair distribution function, which evidence a transition toward a new amorphous electronic excited state close in bonding/structure to the liquid state. The results shed a new light on the optically highly excited states in chalcogenide materials involved in both important processes: phase‐change materials in memory devices and ovonic threshold switching phenomenon induced by a static field.

show abstract

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Sub‐Picosecond Non‐Equilibrium States in the Amorphous Phase of GeTe Phase‐Change Material Thin Films

et al. 2021

Self Cite

View full text Add to dashboard Cite

show abstract

“…Any random physical process is a potential candidate for the realization of PUFs. Indeed, there is already a plethora of research accounts 12 – 19 that include exotic solutions like aerogels 20 , Raman tags 21 , plasmonic nanopapers 22 wrinkles on glasses 23 , perovskite fluorescent dots 24 or even edible unclonable functions 25 to name a few. The PUF scenery in the literature is evolving fast necessitating taxonomy activities like the one presented by McGrath and co authors 12 .…”

Section: Introductionmentioning

confidence: 99%

“…In most PUF demonstrations, although security of goods and services is evoked, it is surprising that these are rarely assessed in terms of practical implementation both in terms of industrial compatibility for upscaled production and PUF evaluation apparatus for Challenge Response Pair (CRP) behavior at the end user. In this context, it is hard to envisage how the various demonstrations like 20 , 23 , 24 mentioned above will be incorporated in an industrial fabrication of everyday goods or how bulky machinery, such as the spectroscopic equipment required in Ref. 21 , can be used for read out of PUF response somewhere in the supply chain.…”

Section: Introductionmentioning

confidence: 99%

Laser fabrication and evaluation of holographic intrinsic physical unclonable functions

Anastasiou

Zacharaki

Tsakas

et al. 2022

Sci Rep

View full text Add to dashboard Cite

Optical Physical Unclonable Functions (PUFs) are well established as the most powerful anticounterfeiting tool. Despite the merits of optical PUFs, widespread use is hindered by existing implementations that are complicated and expensive. On top, the overwhelming majority of optical PUFs refer to extrinsic implementations. Here we overcome these limitations to demonstrate for the first time strong intrinsic optical PUFs with exceptional security characteristics. In doing so, we use Computer-Generated Holograms (CGHs) as optical, intrinsic, and image-based PUFs. The required randomness is offered by the non-deterministic fabrication process achieved with industrial friendly, nanosecond pulsed fiber lasers. Adding to simplicity and low cost, the digital fingerprint is derived by a setup which is designed to be adjustable in a production line. In addition, we propose a novel signature encoding and authentication mechanism that exploits manifold learning techniques to efficiently differentiate data reconstruction-related variation from counterfeit attacks. The proposed method is applied experimentally on silver plates. The robustness of the fabricated intrinsic optical PUFs is evaluated over time. The results have shown exceptional values for robustness and a probability of cloning up to $$10^{-14}$$ 10 - 14 , which exceeds the standard acceptance rate in security applications.

show abstract

“…[ 24 ] While, this flexible PUF is a contact and non‐optical PUF without biocompatibility. Optical PUFs, as a typical example of non‐silicon PUFs, have been studied extensively, [ 25,26 ] which have been applied for different scenarios due to the non‐contact and fast optical reading properties. [ 11,12,27 ] However, most of the optical PUFs are rigid without good biocompatibility and flexibility, which cannot be applied for products with complex surface, and thus limiting their application.…”

Section: Introductionmentioning

confidence: 99%

Flexible and Biocompatible Physical Unclonable Function Anti‐Counterfeiting Label

Zhang²,

Wang

et al. 2021

Adv Funct Materials

View full text Add to dashboard Cite

Optical physical unclonable functions (PUFs) have been proven to be one of the most effective anti‐counterfeiting strategies. However, optical PUFs endowed with flexibility and biocompatibility have not been developed, limiting their application scenarios. Herein, biocompatible and flexible optical PUF labels are developed by randomly embedding microdiamonds in silk fibroin films. The PUF labels can be conformally attached onto the surface of complex shaped objects, providing the desired protection against fake and interior products. In this system, silk fibroin films serve as a flexible and biocompatible substrate, while the Raman signal of the microdiamonds serves as response of the excitation. The extremely high stability and random distribution of the microdiamonds ensure the performance of PUFs, and the maximum encoding capability of 210000 is finally realized. The cytotoxicity analysis results also verify the biosafety of the PUF system. In addition, the as‐prepared PUF labels are attached onto the surface of polyethylene material, and human skin, and even have been implanted under chicken skin tissue, promising their practical applications.

show abstract

Laser Generation of Sub‐Micrometer Wrinkles in a Chalcogenide Glass Film as Physical Unclonable Functions

Cited by 24 publications

References 29 publications

Sub‐Picosecond Non‐Equilibrium States in the Amorphous Phase of GeTe Phase‐Change Material Thin Films

Sub‐Picosecond Non‐Equilibrium States in the Amorphous Phase of GeTe Phase‐Change Material Thin Films

Laser fabrication and evaluation of holographic intrinsic physical unclonable functions

Flexible and Biocompatible Physical Unclonable Function Anti‐Counterfeiting Label

Contact Info

Product

Resources

About