From Classical to Quantum Models: The Regularising Rôle of Integrals, Symmetry and Probabilities

In physics, one is often misled in thinking that the mathematical model of a system is part of or is that system itself. Think of expressions commonly used in physics like “point” particle, motion “on the line”, “smooth” observables, wave function, and even “going to infinity”, without forgetting perplexing phrases like “classical world” versus “quantum world”.... On the other hand, when a mathematical model becomes really inoperative in regard with correct predictions, one is forced to replace it with a new one. It is precisely what happened with the emergence of quantum physics. Classical models were (progressively) superseded by quantum ones through quantization prescriptions. These procedures appear often as ad hoc recipes. In the present paper, well defined quantizations, based on integral calculus and Weyl–Heisenberg symmetry, are described in simple terms through one of the most basic examples of mechanics. Starting from (quasi-) probability distribution(s) on the Euclidean plane viewed as the phase space for the motion of a point particle on the line, i.e., its classical model, we will show how to build corresponding quantum model(s) and associated probabilities (e.g. Husimi) or quasi-probabilities (e.g. Wigner) distributions. We highlight the regularizing rôle of such procedures with the familiar example of the motion of a particle with a variable mass and submitted to a step potential.

[1]  R. Murenzi,et al.  More quantum centrifugal effect in rotating frame , 2017, 1704.02832.

[2]  F. Berezin General concept of quantization , 1975 .

[3]  E.,et al.  Calculus for Functions of Noncommuting Operators and General Phase-Space Methods in Quantum Mechanics . II . Quantum Mechanics in Phase Space * , 2011 .

[4]  N. P. Landsman Between classical and quantum , 2005 .

[5]  Jean-Pierre Gazeau,et al.  Weyl-Heisenberg integral quantization(s): a compendium , 2017, 1703.08443.

[6]  J. Gazeau,et al.  Integral quantizations with two basic examples , 2013, 1308.2348.

[7]  J. Gazeau,et al.  Three examples of quantum dynamics on the half-line with smooth bouncing , 2017, 1708.06422.

[8]  A. Perelomov Generalized Coherent States and Their Applications , 1986 .

[9]  A. S. Wightman,et al.  On the Localizability of Quantum Mechanical Systems , 1962 .

[10]  L. Cohen Generalized Phase-Space Distribution Functions , 1966 .

[11]  A. Barut,et al.  Theory of group representations and applications , 1977 .

[12]  Milton Abramowitz,et al.  Handbook of Mathematical Functions with Formulas, Graphs, and Mathematical Tables , 1964 .

[13]  Girish S. Agarwal,et al.  Calculus for functions of noncommuting operators and general phase-space methods in quantum mechanics. II. Quantum mechanics in phase space , 1970 .

[14]  Romain Murenzi,et al.  Covariant affine integral quantization(s) , 2015, 1512.08274.

[15]  S. Ali,et al.  QUANTIZATION METHODS: A GUIDE FOR PHYSICISTS AND ANALYSTS , 2004, math-ph/0405065.

[16]  I. M. Glazman,et al.  Theory of linear operators in Hilbert space , 1961 .

[17]  Ahmed Youssef,et al.  Are the Weyl and coherent state descriptions physically equivalent , 2013 .

[18]  J. Neumann Mathematical Foundations of Quantum Mechanics , 1955 .

[19]  E. Wigner,et al.  Representations of the Galilei group , 1952 .

[20]  Maurice de Gosson,et al.  Born-Jordan quantization , 2016 .

[21]  J. M. Lévy-Leblond,et al.  The pedagogical role and epistemological significance of group theory in quantum mechanics , 1974 .

[22]  Lévy-Leblond Position-dependent effective mass and Galilean invariance. , 1995, Physical review. A, Atomic, molecular, and optical physics.

[23]  David L. Neuhoff,et al.  Quantization , 2022, IEEE Trans. Inf. Theory.

[24]  J. Lévy-Leblond Elementary quantum models with position-dependent mass , 1992 .

[25]  L. Cohen The Weyl Operator and its Generalization , 2012 .

[26]  J. Neumann Die Eindeutigkeit der Schrödingerschen Operatoren , 1931 .

[27]  J. Gazeau,et al.  Quantum localisation on the circle , 2017, 1708.03693.

[28]  E. Cordero,et al.  On the Invertibility of Born-Jordan Quantization , 2015, 1507.00144.