Enhanced enstrophy generation for turbulent convection in low-Prandtl-number fluids

Schumacher, Jörg; Götzfried, Paul; Scheel, Janet

doi:10.1073/pnas.1505111112

Cited by 40 publications

(62 citation statements)

References 36 publications

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“…At Ra 2 × 10 9 , Cioni et al[90] find a N u ∼ Ra 2/7 scaling, consistent with P r 1 results albeit with a different constant prefactor[91]. At lower Rayleigh numbers ( 5 × 10 8 ), though, studies find an α NR 1/4 scaling where the heat transfer is controlled by inertially-driven, container-scale flows in the bulk rather than by viscous boundary layer processes [e.g.,39,90,[92][93][94]. King and Aurnou[39] find that their liquid gallium rotating convection cases conform to this nonrotating scaling for Ra UNR (E 2 /P r)…”

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confidence: 71%

A heuristic framework for next-generation models of geostrophic convective turbulence

Cheng

Aurnou

Julien

et al. 2018

Geophysical & Astrophysical Fluid Dynamics

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Many geophysical and astrophysical phenomena are driven by turbulent fluid dynamics, containing behaviors separated by tens of orders of magnitude in scale. While direct simulations have made large strides toward understanding geophysical systems, such models still inhabit modest ranges of the governing parameters that are difficult to extrapolate to planetary settings. The canonical problem of rotating Rayleigh-Bénard convection provides an alternate approach -isolating the fundamental physics in a reduced setting. Theoretical studies and asymptotically-reduced simulations in rotating convection have unveiled a variety of flow behaviors likely relevant to natural systems, but still inaccessible to direct simulation. In lieu of this, several new large-scale rotating convection devices have been designed to characterize such behaviors. It is essential to predict how this potential influx of new data will mesh with existing results. Surprisingly, a coherent framework of predictions for extreme rotating convection has not yet been elucidated. In this study, we combine asymptotic predictions, laboratory and numerical results, and experimental constraints to build a heuristic framework for cross-comparison between a broad range of rotating convection studies. We categorize the diverse field of existing predictions in the context of asymptotic flow regimes. We then consider the physical constraints that determine the points of intersection between flow behavior predictions and experimental accessibility. Applying this framework to several upcoming devices demonstrates that laboratory studies may soon be able to characterize geophysically-relevant flow regimes. These new data may transform our understanding of geophysical and astrophysical turbulence, and the conceptual framework developed herein should provide the theoretical infrastructure needed for meaningful discussion of these results. ARTICLE HISTORY

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mentioning

confidence: 71%

A heuristic framework for next-generation models of geostrophic convective turbulence

Cheng

Aurnou

Julien

et al. 2018

Geophysical & Astrophysical Fluid Dynamics

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“…Recent research progress on low-Prandtl number convection includes Vogt et al's 10 discovery that large-scale circulation takes the form of a jump rope vortex in cells of aspect ratio higher than unity when using liquid gallium as the working fluid. Schumacher et al 11 found that the generation of small-scale vorticity in the bulk convection follows the same mechanisms as idealized isotropic turbulence for low-Prandtl number convection. Scheel and Schumacher 2 identified a transition between the rotationally constrained and the weakly rotating turbulent states in rotating Rayleigh-Bénard convection with liquid gallium that differs substantially from moderate-Prandtl number convection.…”

Section: Introductionmentioning

confidence: 93%

“…Scheel and Schumacher 2 identified a transition between the rotationally constrained and the weakly rotating turbulent states in rotating Rayleigh-Bénard convection with liquid gallium that differs substantially from moderate-Prandtl number convection. The main differences are due to the more diffuse temperature field, more vigorous velocity field, and coarser yet fewer production of thermal plumes in low-Prandtl number convection [11][12][13] .…”

Section: Introductionmentioning

confidence: 99%

Statistics of temperature and thermal energy dissipation rate in low-Prandtl number turbulent thermal convection

Shi

2019

Physics of Fluids

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We report the statistical properties of temperature and thermal energy dissipation rate in low-Prandtl number turbulent Rayleigh-Bénard convection. High resolution twodimensional direct numerical simulations were carried out for the Rayleigh number (Ra) of 10 6 ≤ Ra ≤ 10 7 and the Prandtl number (Pr) of 0.025. Our results show that the global heat transport and momentum scaling in terms of Nusselt number (Nu) and Reynolds number (Re) are Nu = 0.21Ra 0.25 and Re = 6.11Ra 0.50 , respectively, indicating that the scaling exponents are smaller than those for moderate-Prandtl number fluids (such as water or air) in the same convection cell. In the central region of the cell, probability density functions (PDFs) of temperature profiles show stretched exponential peak and the Gaussian tail; in the sidewall region, PDFs of temperature profiles show a multimodal distribution at relative lower Ra, while they approach the Gaussian profile at relative higher Ra. We split the energy dissipation rate into contributions from bulk and boundary layers and found the locally averaged thermal energy dissipation rate from the boundary layer region is an order of magnitude larger than that from the bulk region. Even if the much smaller volume occupied by the boundary layer region is considered, the globally averaged thermal energy dissipation rate from the boundary layer region is still larger than that from the bulk region. We further numerically determined the scaling exponents of globally averaged thermal energy dissipation rates as functions of Ra and Re. a a) This article may be downloaded for personal use only. Any other use requires prior permission of the author and AIP Publishing. This article appeared in Xu et al., Phys. Fluids 31, 125101 (2019) and may be found at

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“…These are the experiments by Glazier et al [22] up to Ra = 8 × 10 10 for mercury and Horanyi et al [21] up to Ra = 5 × 10 6 for sodium. Three of our simulations are on a line of constant Grashof number Gr = Ra/P r which has been discussed in [20]. The constant Gr data points are connected by the inclined red line.…”

Section: Figmentioning

confidence: 99%

Predicting transition ranges to fully turbulent viscous boundary layers in low Prandtl number convection flows

Scheel

Schumacher

2017

Phys. Rev. Fluids

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We discuss two aspects of turbulent Rayleigh-Bénard convection (RBC) on the basis of highresolution direct numerical simulations in a unique setting; a closed cylindrical cell of aspect ratio of one. First, we present a comprehensive comparison of statistical quantities such as energy dissipation rates and boundary layer thickness scales. Data are used from three simulation run series at Prandtl numbers P r that cover two orders of magnitude. In contrast to most previous studies in RBC the focus of the present work is on convective turbulence at very low Prandtl numbers including P r = 0.021 for liquid mercury or gallium and P r = 0.005 for liquid sodium. In this parameter range of RBC, inertial effects cause a dominating turbulent momentum transport that is in line with highly intermittent fluid turbulence both in the bulk and in the boundary layers and thus should be able to trigger a transition to the fully turbulent boundary layers of the ultimate regime of convection for higher Rayleigh number. Secondly, we predict the ranges of Rayleigh numbers for which the viscous boundary layer will transition to turbulence and the flow as a whole will cross over into the ultimate regime. These transition ranges are obtained by extrapolation from our simulation data. The extrapolation methods are based on the large-scale properties of the velocity profile. Two of the three methods predict similar ranges for the transition to ultimate convection when their uncertainties are taken into account. All three extrapolation methods indicate that the range of critical Rayleigh numbers Rac is shifted to smaller magnitudes as the Prandtl number becomes smaller.

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Enhanced enstrophy generation for turbulent convection in low-Prandtl-number fluids

Cited by 40 publications

References 36 publications

A heuristic framework for next-generation models of geostrophic convective turbulence

A heuristic framework for next-generation models of geostrophic convective turbulence

Statistics of temperature and thermal energy dissipation rate in low-Prandtl number turbulent thermal convection

Predicting transition ranges to fully turbulent viscous boundary layers in low Prandtl number convection flows

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