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Halide perovskite memristors as flexible and reconfigurable physical unclonable functions

Rohit Abraham John, Nimesh Shah, Sujaya Kumar Vishwanath, Si En Ng, Benny Febriansyah, Metikoti Jagadeeswararao, Chip-Hong Chang, Arindam Basu, Nripan Mathews

2021Nature Communications263 citationsDOIOpen Access PDF

Abstract

Abstract Physical Unclonable Functions (PUFs) address the inherent limitations of conventional hardware security solutions in edge-computing devices. Despite impressive demonstrations with silicon circuits and crossbars of oxide memristors, realizing efficient roots of trust for resource-constrained hardware remains a significant challenge. Hybrid organic electronic materials with a rich reservoir of exotic switching physics offer an attractive, inexpensive alternative to design efficient cryptographic hardware, but have not been investigated till date. Here, we report a breakthrough security primitive exploiting the switching physics of one dimensional halide perovskite memristors as excellent sources of entropy for secure key generation and device authentication. Measurements of a prototypical 1 kb propyl pyridinium lead iodide (PrPyr[PbI 3 ]) weak memristor PUF with a differential write-back strategy reveals near ideal uniformity, uniqueness and reliability without additional area and power overheads. Cycle-to-cycle write variability enables reconfigurability, while in-memory computing empowers a strong recurrent PUF construction to thwart machine learning attacks.

Topics & Concepts

Physical unclonable functionHalideMemristorPerovskite (structure)Materials scienceOptoelectronicsNanotechnologyComputer scienceEmbedded systemElectronic engineeringChemistryEngineeringCryptographyCrystallographyComputer securityInorganic chemistryAdvanced Memory and Neural ComputingNeuroscience and Neural EngineeringPhysical Unclonable Functions (PUFs) and Hardware Security
Halide perovskite memristors as flexible and reconfigurable physical unclonable functions | Litcius