Litcius/Paper detail

Tunable, Hardware-Based Quantum Random Number Generation Using Coupled Quantum Dots

Heath McCabe, Scott Koziol, Gregory L. Snider, Enrique P. Blair

2020IEEE Transactions on Nanotechnology19 citationsDOIOpen Access PDF

Abstract

Random numbers are a valuable commodity in gaming and gambling, simulation, conventional and quantum cryptography, and in non-conventional computing schemes such as stochastic computing. We propose to generate a random bit using a position measurement of a single mobile charge on a coupled pair of quantum dots. True randomness of the measurement outcome is provided by quantum mechanics via Born's rule. A random bit string may be generated using a sequence of repeated measurements on the same double quantum dot (DQD) system. Any bias toward a “0” measurement or a “1” measurement may be removed or tuned as desired simply by adjusting the detuning between localized states. Device tunability provides versatility, enabling this quantum random number generator (QRNG) to support applications in which no bias is desired, or where a tunable bias is desired. We discuss a metal-dot implementation as well as a molecular implementation of this QRNG. Basic quantum mechanical principles are used to study power dissipation and timing considerations for the generation of random bit strings. The DQD offers a small form factor and, in a metallic implementation, is usable in the case where cryogenic operations are desirable (as in the case of quantum computing). For room-temperature applications, a molecular DQD may be used.

Topics & Concepts

Random number generationRandomnessComputer scienceRandom accessQuantum dotQuantumCoin flippingPhysicsQuantum mechanicsElectronic engineeringAlgorithmMathematicsEngineeringOperating systemStatisticsQuantum-Dot Cellular AutomataQuantum Computing Algorithms and ArchitectureAdvanced Memory and Neural Computing