On Hydrodynamic Formulations of Quantum Mechanics and the Problem of Sparse Ontology
- URL: http://arxiv.org/abs/2602.21106v1
- Date: Tue, 24 Feb 2026 17:03:49 GMT
- Title: On Hydrodynamic Formulations of Quantum Mechanics and the Problem of Sparse Ontology
- Authors: Aric Hackebill, Bill Poirier,
- Abstract summary: Hydrodynamic reformulations of the Schrdinger equation suggest an interpretation of quantum mechanics in terms of a fluid flowing on configuration space.<n>In the discrete hydrodynamic view, this fluid is not fundamental but emerges from many underlying microscopic fluid components.<n>We argue that all discrete hydrodynamic models face a generic structural difficulty, which we call the problem of sparse ontology.
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- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Hydrodynamic reformulations of the Schrödinger equation suggest an interpretation of quantum mechanics in terms of a fluid flowing on configuration space. In the discrete hydrodynamic view, this fluid is not fundamental but emerges from many underlying microscopic fluid components whose collective behavior reproduces quantum phenomena. The most developed realization of this idea is the discrete many interacting worlds (MIW) framework, in which discrete particle-like worlds interact via inter-world forces and quantum probabilities are grounded in direct world counting. But there is also an older, continuous version of MIW. After reviewing the hydrodynamic and MIW formalisms, and emphasizing some of their interpretational advantages over the Everettian Many Worlds and Bohmian approaches, we argue that all discrete hydrodynamic models face a generic structural difficulty, which we call the problem of sparse ontology. Because wavefunctions typically branch under decoherence, the discrete components of the fluid are repeatedly partitioned into sub-ensembles, thereby thinning their density in configuration space and driving the dynamics away from the quantum regime once the components become sufficiently sparse. We conclude that successful hydrodynamic completions of quantum mechanics plausibly require an essentially continuous ontology.
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