Description of the Simplest Non-Markov Process Using a Differential Equation for the Quantum State Vector
( Pp. 9-15)
More about authors
Ozhigov Yuri I.
Doctor of Physics and Mathematics; Professor at the Department of Supercomputers and Quantum Informatics of the Faculty of Computational Mathematics and Cybernetics
Lomonosov Moscow State University
Moscow, Russian Federation Victorova Nadezda B. Candidate of Physics and Mathematics; associated professor at the Department of Fundamental and Applied Mathematics of the Faculty of Information Systems and Security of the Institute of IT and Security Technologies of the Russian State University for the Humanities. Moscow, Russian Federation. Author ID: 4690; E-mail: nbvictorova@list.ru
Valiev Institute of Physics and Technology of the Russian Academy of Sciences
Moscow, Russian Federation
Lomonosov Moscow State University
Moscow, Russian Federation Victorova Nadezda B. Candidate of Physics and Mathematics; associated professor at the Department of Fundamental and Applied Mathematics of the Faculty of Information Systems and Security of the Institute of IT and Security Technologies of the Russian State University for the Humanities. Moscow, Russian Federation. Author ID: 4690; E-mail: nbvictorova@list.ru
Valiev Institute of Physics and Technology of the Russian Academy of Sciences
Moscow, Russian Federation
Abstract:
The Jaynes–Cummings model with one atom and a photon is considered. A photon leaks out of the cavity (optical resonator). An atom can be in an excited and ground state. Usually, the dynamics of the probability of finding a photon in a cavity is considered using the basic quantum Lindblad equation, in which the density matrix acts as an unknown function. The Lindblad equation describes a quantum Markov random process. The article attempts to replace the equation from the density matrix with an ersatz of the Lindblad equation, which is a differential equation from the state wave vector. The quantum master equation involves the use of a matrix with a dimension equal to the dimension of the state space, which increases the complexity of the calculations, since it requires a quadratically large memory. For example, for the dimension of the main space equal to a billion, the memory required to solve the basic quantum equation will be about a quintillion, which is a problem even for supercomputers. Whereas a billion-long column fits easily into the memory of a personal computer and can be easily processed on a personal laptop. The ersatz of the quantum master equation, which we are constructing, cannot accurately describe the dynamics of the density matrix and therefore cannot serve as an exact replacement for the quantum master equation. Our ersatz will describe a special process of exchange with the environment.
How to Cite:
Ozhigov Yu.I., Victorova N.B. Description of the Simplest Non-Markov Process Using a Differential Equation for the Quantum State Vector. Computational Nanotechnology. 2023. Vol. 10. No. 2. Pp. 9–15. (In Rus.) DOI: 10.33693/2313-223X-2023-10-2-9-15. EDN: AIXNRU
Reference list:
Ozhigov Yu., You J. Description of the non-Markovian dynamics of atoms in terms of a pure state. Computational Mathematics and Modeling. 2023. URL: https://arxiv.org/pdf/2305.00564.pdf
Jaynes E.T., Cummings F.W. Comparison of quantum and semiclassical radiation theories with application to the beam maser. Proc. IEEE. 1963. Vol. 51. No. 1. Pp. 89–109. DOI: 1.0.1109/PROC.1963.1664
Cummings F.W. Reminiscing about thesis work with E.T. Jaynes at Stanford in the 1950s. Journal of Physics B: Atomic, Molecular and Optical Physics. 2013. Vol. 46. No. 22. P. 220202(3pp). DOI: 10.1088/0953-4075/46/22/220202
Ozhigov Y. Quantum computer. Moscow: Max Press, 2020. 172 p. ISBN: 9788-5-317-06405-7
Scovoroda N.A., Ozhigov Yu.I., Victorova N.B. Quantum revivals of a non-rabi type in a Jaynes–Cummings model. Theoretical and Mathematical Physics. 2016. No. 189 (2). Pp. 1673–1679.
Viktorova N., Ozhigov Yu.I., Skovoroda N.A., Skurat K.N. Analytical solution of the quantum master equation for the Jaynes–Cummings model. Computational Mathematics and Modeling. 2019. Vol. 30. No. 1. Pp. 68–79. URL: https://rdcu.be/bfRRR
Jaynes E.T., Cummings F.W. Comparison of quantum and semiclassical radiation theories with application to the beam maser. Proc. IEEE. 1963. Vol. 51. No. 1. Pp. 89–109. DOI: 1.0.1109/PROC.1963.1664
Cummings F.W. Reminiscing about thesis work with E.T. Jaynes at Stanford in the 1950s. Journal of Physics B: Atomic, Molecular and Optical Physics. 2013. Vol. 46. No. 22. P. 220202(3pp). DOI: 10.1088/0953-4075/46/22/220202
Ozhigov Y. Quantum computer. Moscow: Max Press, 2020. 172 p. ISBN: 9788-5-317-06405-7
Scovoroda N.A., Ozhigov Yu.I., Victorova N.B. Quantum revivals of a non-rabi type in a Jaynes–Cummings model. Theoretical and Mathematical Physics. 2016. No. 189 (2). Pp. 1673–1679.
Viktorova N., Ozhigov Yu.I., Skovoroda N.A., Skurat K.N. Analytical solution of the quantum master equation for the Jaynes–Cummings model. Computational Mathematics and Modeling. 2019. Vol. 30. No. 1. Pp. 68–79. URL: https://rdcu.be/bfRRR
Keywords:
quantum informatics, Lindblad equation, system of differential equations, eigenvectors and eigenvalues, Rabi oscillations, Jaynes–Cummings model.
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