Multi-scale physics of cryogenic liquid helium-4: Inverse coarse-graining properties of smoothed particle hydrodynamics

Multi-scale physics of cryogenic liquid helium-4: Inverse coarse-graining properties of smoothed particle hydrodynamics

Our recent numerical studies on cryogenic liquid helium-4 highlight key features of multiscale physics that can be captured using the two-fluid model. In this paper, we demonstrated that classical and quantum hydrodynamic two-fluid models are connected via scale transformations: large eddy simulatio...

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Bibliographic Details
Main Author: Satori Tsuzuki
Format: Article
Language:English
Published: IOP Publishing 2025-01-01
Series:Journal of Physics Communications
Subjects:
multi-scale physics
quantum hydrodynamics
cryogenic liquid helium-4
smoothed particle hydrodynamics
inverse coarse-graining effects
large eddy simulation
Online Access:https://doi.org/10.1088/2399-6528/ade35f
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Summary:Our recent numerical studies on cryogenic liquid helium-4 highlight key features of multiscale physics that can be captured using the two-fluid model. In this paper, we demonstrated that classical and quantum hydrodynamic two-fluid models are connected via scale transformations: large eddy simulation (LES) filtering links microscopic to macroscopic scales, while inverse scale transformation through SPH connects macro back to microscales. We showed that the spin angular momentum conservation term, introduced as a quantum-like correction, formally corresponds to a subgrid-scale (SGS) model derived from this transformation. Moreover, solving the classical hydrodynamic two-fluid model with SPH appears to reproduce microscopic-scale fluctuations at macroscopic scales. In particular, the amplitude of these fluctuations depends on the kernel radius. This effect may be attributed to truncation errors from kernel smoothing, which can qualitatively resemble such fluctuations; however, this resemblance lacks first-principle justification and should be viewed as a speculative analogy rather than a physically grounded effect. Our theoretical analysis further suggests that the Condiff viscosity model can act as an SGS model, incorporating quantum vortex interactions under point-vortex approximation into the two-fluid framework. These findings provide new insight into the microscopic structure of cryogenic helium-4 within a multiscale context. Notably, the normal fluid can be understood as a mixture of inviscid and viscous fluid particles. While molecular viscosity renders the normal fluid at microscopic scales, its small magnitude contributes little to the large-scale effective viscosity, which includes both molecular and eddy viscosities; therefore, in laminar regimes where eddy viscosity is negligible, the normal fluid may be effectively treated as inviscid at large scales if molecular viscosity is sufficiently small.
ISSN:2399-6528

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