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The continuity equation and the Hamiltonian formalism in quantum mechanics

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Abstract

The relationship between the continuity equation and the HamiltonianH of a quantum system is investigated from a nonstandard point of view. In contrast to the usual approaches, the expression of the current densityJ ψ is givenab initio by means of a transport-velocity operatorV T, whose existence follows from a “weak” formulation of the correspondence principle. Once given a Hilbert-space metricM, it is shown that the equation of motion and the continuity equation actually represent a system in theunknown operatorsH andV T, due to the arbitrariness on the initial condition of the quantum state. The general solution is given in some cases of special interest and a straightforward application to relativistic quantum mechanics is performed.

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This work was partially supported by the Ministero della Pubblica Istruzione.

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Ferrari, L. The continuity equation and the Hamiltonian formalism in quantum mechanics. Found Phys 17, 329–343 (1987). https://doi.org/10.1007/BF00733372

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  • DOI: https://doi.org/10.1007/BF00733372

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