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Practical Security of RSA Against NTC-Architecture Quantum Computing Attacks

Kai Li, Qing-yu Cai

2021International Journal of Theoretical Physics11 citationsDOIOpen Access PDF

Abstract

Abstract Quantum algorithms can greatly speed up computation in solving some classical problems, while the computational power of quantum computers should also be restricted by laws of physics. Due to quantum time-energy uncertainty relation, there is a lower limit of the evolution time for a given quantum operation, and therefore the time complexity must be considered when the number of serial quantum operations is particularly large. When the key length is about at the level of KB (encryption and decryption can be completed in a few minutes by using standard programs), it will take at least 50-100 years for NTC (Neighbor-only, Two-qubit gate, Concurrent) architecture ion-trap quantum computers to execute Shor’s algorithm. For NTC architecture superconducting quantum computers with a code distance 27 for error-correcting, when the key length increased to 16 KB, the cracking time will also increase to 100 years that far exceeds the coherence time. This shows the robustness of the updated RSA against practical quantum computing attacks.

Topics & Concepts

Quantum computerComputer scienceKey sizeQuantum cryptographyQuantum algorithmQubitQuantumQuantum error correctionTheoretical computer scienceQuantum informationComputer engineeringEncryptionAlgorithmComputational scienceQuantum mechanicsPhysicsPublic-key cryptographyComputer securityQuantum Computing Algorithms and ArchitectureQuantum Information and CryptographyQuantum-Dot Cellular Automata
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