A fast quantum mechanical algorithm for database search
STOC '96 Proceedings of the twenty-eighth annual ACM symposium on Theory of computing
Polynomial-Time Algorithms for Prime Factorization and Discrete Logarithms on a Quantum Computer
SIAM Journal on Computing
An introduction to quantum computing for non-physicists
ACM Computing Surveys (CSUR)
Feynman Lectures on Computation
Feynman Lectures on Computation
A quantum algorithm for finding length of shortest path in the connected weighted graph
PDCN '08 Proceedings of the IASTED International Conference on Parallel and Distributed Computing and Networks
PEA: Polymorphic Encryption Algorithm based on quantum computation
International Journal of Systems, Control and Communications
ADNTIIC'10 Proceedings of the First international conference on Advances in new technologies, interactive interfaces, and communicability
Feature: The Impact of Quantum Computing on Cryptography
Network Security
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Today's computers operate on the same fundamental principle as the mechanical devices dreamed up by Charles Babbage in the 19th century and later formalized by Alan Turing: One stable state of the machine represents one number. Even seemingly nonstandard computation models, such as the one based on DNA, share this basic principle. Recently, physicists and computer scientists have realized that not only do their ideas about computing rest on partly accurate principles, but they miss out on a whole class of computation. Quantum physics offers powerful methods of encoding and manipulating information that are not possible within a classical framework. The potential applications of these quantum information-processing methods include provably secure key distribution for cryptography, rapid integer factoring, and quantum simulation. The authors discuss the directions that quantum information theory appears to be heading and the research and applications it has accrued.