___

• C. Shannon, “A mathematical theory of communication,” Bell Syst. Tech. J., 27, 379-423, 1948.
• C.E. Shannon, W. Weaver, The Mathematical Theory of Communication, v. 1, University of Illinois Press, Urbana, Illinois, 1-131, 1964.
• M.A. Nielsen, I.L. Chuang. Quantum Computation and Quantum Information, Cambridge University Press, Cambridge, 2000.
• E.T. Jaynes, “Information theory and statistical mechanics,” Phys. Rev., 106 (4), 620–630, 1957.
• S. Zhang, J. Li. “A bound on expectation values and variances of quantum observables via Renyi entropy and Tsallis entropy,” Int. J. Quantum. Inf., 19, 2150019, 2021.
• J. Acharya, I. Issa, N.V. Shende, A. B. Wagner. “Measuring Quantum Entropy,“ arXiv:1711.00814. 2017.
• L. Brillouin, “Science and Information Theory,” Physics Today, 9(12), 39, 1956.
• P. Facchi, G. Gramegna, A. Konderak. “Entropy of quantum states,” arXiv:2104.12611. 2021.
• I. Bialynicki-Birula and J. Mycielski, “Uncertainty relations for information entropy in wave mechanics”, Comm. Math. Phys. 44, 129-132, 1975.
• F. C. E. Lima, a. R. P. Moreira, c. A. S. Almeida, “Information and thermodynamic properties of a non-hermetian particle ensemble,“ arXiv:2101.04803. 2021.
• F. C. E. Lima, a. R. P. Moreira, L.E.S. Machado, A. S. Almeida. “Statistical properties of linear Majorana fermions,” Int. J. Quant. Chem. 121, e26749, 2021.
• F. C. E. Lima. “Quantum information entropies for a soliton at hyperbolic well,|” arXiv:2110.11195. 2021.
• R.S. Carrillo, C.A. Gil-Barrera, G.H. Sun, et al, “Shannon entropies of asymmetric multiple quantum well systems with a constant total length,” Eur. Phys. J. Plus 136, 1060, 2021.
• R. Khordad, A. Ghanbari, A. Ghaffaripour. “Effect of confining potential on information entropy measures in hydrogen atom: extensive and non-extensive entropy,” Indian J. Phys, 94 (12), 2020.
• S. Martiniani, P.M. Chaikin, D. Levine, “Quantifying hidden order out of equilibrium,” Phys. Rev. X 9, 011031, 2019.
• O. Bahadır, H. Türkmençalıkoğlu, "Bilgi Kuramında Shannon Entropisi ve Uygulamaları," Eur. J. Sci. Tech., Special Issue 32, pp. 491-497, 2021.
• K.E. Drexler, Nanosystems: Molecular machinery, Manufacturing, and computation, 1st Ed. Wiley, Hoboken, 576, 1992.
• R. Nalewajski, “On entropy/information continuity in molecular electronic states,” Mol. Phys. 114 (1), 1225-1235, 2016.
• M. Fannes, “Continuity property of the entropy density for spin lattice systems,” Commun. Math. Phys. 31 (4), 291–294, 1973.
• KMR Audenaert, “A sharp continuity estimate for the von Neumann entropy,” J. Phys. A Math. Theor. 40 (28) 8127-8137, 2007.
• T.R. Gingrich, J.M. Horowitz, N. Perunov at al, “Dissipation Bounds All Steady-State Current Fluctuations,” Phys. Rev. Lett. 116 (12), 120601, 2016.
• P. Pietzonka P, A. Barato, U. Seifert, “Universal bounds on current fluctuations,” Phys. Rev., E 93, 052145, 2016.
• A. Moldavanov, “Theoretical Aspects of Radiative Energy Transport for Nanoscale System: Thermodynamic Uncertainty,” J. Comput. Theor. Trans, 50(3), 236-248, 2021.
• N.W. Tschoegl, Fundamentals of Equilibrium and Steady-State Thermodynamics, Elsevier, Amsterdam, 2000.
• R. G. Lerner, G.L. Trigg, Encyclopaedia of Physics 3nd ed. Wiley-VCH Verlag, Weinheim, 1994.
• L.S. Grant, W.R. Phillips, Electromagnetism, 2nd ed., Wiley. Manchester Physics Series, Hoboken, 2008.
• R.A. Serway, J.W. Jewett, V. Peroomian, Physics for scientists and engineers with modern physics. 9th ed. Pacific Grove: Brooks Cole, 2014.
• A. Moldavanov. “Energy Infrastructure of Evolution for System with Infinite Number of Links with Environment,” BioSystems, 213, 104607, 2022.
• A.V. Moldavanov, “Analytical and Numerical Model for Evolution of Minimal Cell with Infinite Number of Energy Links,”: Proceedings Mathematical biology and bioinformatics, Pushino, Russia, 8, article # e16. doi: 10.17537 /icmbb20.15, 2020.
• A. Moldavanov. “Randomized Continuity Equation Model of Energy Transport in Open System,” in AMSM 2017: Proceedings of the 2017 2nd International Conference on Applied Mathematics, Simulation and Modelling, 258 – 265, 2017.
• D. J. C. MacKay, Information Theory, Inference, and Learning Algorithms, Cambridge University Press, Cambridge, 2003.
• J.W. Gibbs, Elementary Principles in Statistical Mechanics. New York: Dover Publications, 1960.
• L. Benguigui, “The different paths to entropy,” arXiv.org Solid State Institute and Physics department Technion Israel Institute of Technology 32000 Haifa. Israel 1-32, 2012.
• C. Marsh, “Introduction to Continuous Entropy,” Department of Computer Science, Princeton University.
• B.P. Levin, Theoretical basics of statistical radio engineering. 3rd revised ed. Radio and communication, Мoscow, 1989.
• R. Swenson, “Emergent attractors and the law of maximum entropy production: Foundations to a theory of general evolution,” Syst. Res. 6(3), 187–197, 1989.
• J. Uffink, J. van Lith. “Thermodynamic uncertainty relations,” Found. Phys. 29 (5), 655-692, 1999.
• J.S. Hsieh, Principles of Thermodynamics. Washington, D.C.: Scripta Book Company, 1975.
• A.E. Shalyt-Margolin, A. Ya. Tregubovich. “Deformed Density Matrix and Generalized Uncertainty Relation in Thermodynamics,” Mod. Phys. Lett. A. 19(1), 71-81, 2004.
• G. Wilk, Z. Włodarczyk. “Application of nonextensive statistics to particle and nuclear physics,” Phys. A: Stat. Mech. Appl. 305 (1-2), 227-233. 2002.
• J. Lindhard, Complementarity’ between energy and temperature, in The Lesson of Quantum Theory. edited by de Boer J, Dal E, Ulfbeck O., 99-112, North-Holland, Amsterdam, 1986.
• A. Faigon, “Uncertainty and Information in Classical Mechanics Formulation. Common Ground for Thermodynamics and Quantum Mechanics,” https://arxiv.org/abs/quant-ph/0311153, 2007.
• J.M. Horowitz, T.R. Gingrich, ”Thermodynamic uncertainty relations constrain non-equilibrium fluctuations,” Nat. Phys. 16, 15–20, 2020.