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A Floer Theoretic Approach to Energy Eigenstates on one Dimensional Configuration Spaces

arXiv
Authors: Kevin Ruck

Year

2026

Paper ID

38948

Status

Preprint

Abstract Read

~2 min

Abstract Words

122

Citations

N/A

Abstract

In this article we consider two classical problems in Quantum Mechanics, namely the 'particle on a ring' and the 'particle in a box' from the viewpoint of symplectic topology. Interpreting the solutions of the corresponding time independent Schrödinger equation as orbits in a suitably chosen time dependent Hamiltonian system allows us to investigate them using Floer theory. More precisely we extend the definition of Rabinowitz Floer homology to non-autonomous Hamiltonians on mathbb{R}2n with its standard symplectic structure and show that compactness of the moduli space of J-holomorphic curves still holds. With this homology we are then able to prove existence results for energy E eigenstates on the 'ring' or in the 'box' for a big range of exterior potentials.

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  • It adds a 2026 reference point for readers tracking recent quantum research.
  • In this article we consider two classical problems in Quantum Mechanics, namely the 'particle on a ring' and the 'particle in a box' from the viewpoint of symplectic topology.

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