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Discrete symmetries in classical and quantum oscillators

Alexander D. Popov

Abstract

We consider the nature of the wave function using the example of a harmonic oscillator. We show that the eigenfunctions $ψ_n{=}z^n$ of the quantum Hamiltonian in the complex Bargmann-Fock-Segal representation with $z\in\mathbb C$ are the coordinates of a classical oscillator with energy $E_n=\hbarωn$, $n=0,1,2,...\,$. They are defined on conical spaces ${\mathbb C}/{\mathbb Z}_n$ with cone angles $2π/n$, which are embedded as subspaces in the phase space $\mathbb C$ of the classical oscillator. Here ${\mathbb Z}_n$ is the finite cyclic group of rotations of the space $\mathbb C$ by an angle $2π/n$. The superposition $ψ=\sum_n c_nψ_n$ of the eigenfunctions $ψ_n$ arises only with incomplete knowledge of the initial data for solving the Schrödinger equation, when the conditions of invariance with respect to the discrete groups ${\mathbb Z}_n$ are not imposed and the general solution takes into account all possible initial data parametrized by the numbers $n\in\mathbb N$.

Discrete symmetries in classical and quantum oscillators

Abstract

We consider the nature of the wave function using the example of a harmonic oscillator. We show that the eigenfunctions of the quantum Hamiltonian in the complex Bargmann-Fock-Segal representation with are the coordinates of a classical oscillator with energy , . They are defined on conical spaces with cone angles , which are embedded as subspaces in the phase space of the classical oscillator. Here is the finite cyclic group of rotations of the space by an angle . The superposition of the eigenfunctions arises only with incomplete knowledge of the initial data for solving the Schrödinger equation, when the conditions of invariance with respect to the discrete groups are not imposed and the general solution takes into account all possible initial data parametrized by the numbers .
Paper Structure (44 equations)

This paper contains 44 equations.