PPT-Hirota Dynamics of Quantum Integrability

Vladimir Kazakov ENS Paris Facets of Integrability Random Patterns Stochastic Processes Hydrodynamics Gauge Theories and Condensed Matter Systems S imons institute . Tucker Yasutaka Hirota Erin J Wamsley Hiuyan Lau Annie Chaklader William Fishbein Laboratory of Cognitive Neuroscience and Sleep The City College of the City University of New York 138th Street and Convent Ave New York NY 10031 USA Received 25 Janua dynamics vs. entang. lement. APS March Meeting. Pittsburgh. , 2009 March 16. . Ramsey . interferometry. and cat . states. Quantum information . perspective. Beyond the Heisenberg . limit. Two-component BECs. (Quantum Cryptography). The BIG Idea. Basic idea of cryptography – To keep information secure from prying eyes. . Current encryption is mathematically based. Basically there are several possible types of keys and if the sender and end user both know the key, they can exchange information securely. . Quantum Hamiltonian Complexity. Aram Harrow (MIT). Simons Institute. 16 Jan 2014. Entanglement. Original motivation for quantum computing. [Feynman ‘82]. Nature isn't classical, dammit, and if you want to make a simulation of Nature, you'd better make it quantum mechanical, and by golly it's a wonderful problem, because it doesn't look so easy.. and . Ultra-Efficient Solar Cells . 2008. “for the Layman”. Disclaimer. The information contained in this document is provided by Phoenix Alliance Corp. through its research sources and is obtained from sources that Phoenix Alliance Corp. believes to be reliable or are otherwise expressions of third party opinion. Whilst Phoenix Alliance Corp. has made reasonable efforts to ensure the accuracy, completeness and appropriateness of such information, any reliance on such information is entirely at the risk of the party using it, and it will not rely on such contents in substitution for making proper and appropriate enquiries from the relevant third parties. . Todd A. Brun, Daniel A. . Lidar. ,. Ben . Reichardt. , Paolo . Zanardi. University of Southern California. The key to quantum computation. The most serious obstacle to realizing quantum computers is . K. Sengupta. Indian Association for the Cultivation of Science, Kolkata. Collaborators: . Shreyoshi. . Mondal. , . Anatoli. . Polkovnikov. , . Diptiman. . Sen. , . Alessandro Silva, . hot atoms. Saikat. Ghosh. Arif. . Warsi, . Niharika. Singh, . Arunabh. Mukherjee. Indian Institute of Technology - Kanpur. Qubits: Superposed atomic states as a resource. Hammerer K, Sorensen A S and . Fang Song. IQC, University of Waterloo. -- “Quantum-Friendly” Reductions. 2. How do . quantum . attacks change classical cryptography?. Crypto-systems based on the hardness of factoring and discrete-log are . McsQPT. ). Joint work with: . S. . Rahimi-Keshari. , A. T. . Rezakhani. , T. C. Ralph. Masoud. Ghalaii. Nov. 2013. 1. Basic concepts—Phase space, Wigner . function, . HD, … . Harmonic oscillator. Lecture . 3. Books Recommended:. Lectures on Quantum Field Theory by Ashok Das. Advanced Quantum Mechanics by . Schwabl. Relativistic Quantum Mechanics by Greiner. . Quantum Field Theory by Mark . Srednicki. . Gödel-Cohen Incompleteness. and the Universe. Luis Gonzalez-Mestres. Cosmology Laboratory, John . Naisbitt. University. Belgrade and Paris. Abstract –. . What is the origin of Quantum Mechanics (QM)? Is it an ultimate principle of Physics or a property of standard particles generated at a more fundamental level?. (1987-2017. ). John F. Stanton. University of Florida. Acknowledgements. Juergen. Gauss. Takatoshi. . Ichino. Chris Simmons. Anna . Krylov. DOE, NSF, Welch Foundation. Imaginary non-symmetric frequency Lower energy structures . Part 1. Outline. Introduction. Problems of classical physics. Black-body Radiation. experimental observations. Wien’s displacement law. Stefan – Boltzmann law. Rayleigh - Jeans. Wien’s radiation law.