TY - JOUR
T1 - Machine Learning Ensures Quantum-Safe Blockchain Availability
AU - Seol, Jongho
AU - Kim, Jongyeop
N1 - Publisher Copyright:
© 2024 International Association for Computer Information Systems.
PY - 2024
Y1 - 2024
N2 - This study explores quantum computing and blockchain, focusing on quantum-safe algorithms. As quantum computing progresses, it threatens blockchain cryptography, necessitating quantum-resistant/safe algorithms. Using statistical analysis and simulations to address future cyber threats, we analyze quantum-safe cryptography in blockchains. We pioneer machine learning models to assess quantum-safe algorithm performance across encryption, key generation, signatures, speed, scalability, energy efficiency, and security. Our analysis, referencing Ethereum’s Ether values, pinpoints areas for quantum-safe cryptography improvements, addressing limitations and proposing solutions to strengthen security and efficiency. In experiments, we observed a 15% increase in encryption strength, 10% enhanced key generation efficiency, and improved reliability parameters. These findings stress the importance of machine learning in quantum-safe cryptography for widespread adoption and long-term security against quantum threats. In conclusion, our research paves the way for the integration of quantum-safe algorithms, ensuring the resilience of blockchain systems in the face of quantum advancements.
AB - This study explores quantum computing and blockchain, focusing on quantum-safe algorithms. As quantum computing progresses, it threatens blockchain cryptography, necessitating quantum-resistant/safe algorithms. Using statistical analysis and simulations to address future cyber threats, we analyze quantum-safe cryptography in blockchains. We pioneer machine learning models to assess quantum-safe algorithm performance across encryption, key generation, signatures, speed, scalability, energy efficiency, and security. Our analysis, referencing Ethereum’s Ether values, pinpoints areas for quantum-safe cryptography improvements, addressing limitations and proposing solutions to strengthen security and efficiency. In experiments, we observed a 15% increase in encryption strength, 10% enhanced key generation efficiency, and improved reliability parameters. These findings stress the importance of machine learning in quantum-safe cryptography for widespread adoption and long-term security against quantum threats. In conclusion, our research paves the way for the integration of quantum-safe algorithms, ensuring the resilience of blockchain systems in the face of quantum advancements.
KW - blockchain security
KW - cryptographic algorithms
KW - ML predictive models
KW - quantum attacks
KW - quantum computing
KW - quantum-resistant/safe
KW - Word
UR - http://www.scopus.com/inward/record.url?scp=85183924834&partnerID=8YFLogxK
U2 - 10.1080/08874417.2024.2308207
DO - 10.1080/08874417.2024.2308207
M3 - Article
AN - SCOPUS:85183924834
SN - 0887-4417
JO - Journal of Computer Information Systems
JF - Journal of Computer Information Systems
ER -