Combined measurement of velocity and temperature in liquid metal convection

Zürner, Till; Schindler, Felix; Vogt, Tobias; Eckert, Sven; Schumacher, Jörg

doi:10.1017/jfm.2019.556

Cited by 68 publications

(120 citation statements)

References 50 publications

(173 reference statements)

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“…The agreement is still good for their 19.1 ± 1.3 with the present value of 21.35 ± 1.83 at Ra = 10 8 even though differences are larger, most probably caused by the different aspect ratios. The magnitude of the turbulent heat transfer agrees also well with measurements by Cioni et al (1997) and Glazier et al (1999) in mercury (Pr = 0.025) and by Zürner et al (2019) in GaInSn for Pr = 0.029, all with Γ = 1.…”

Section: Turbulent Heat and Momentum Transportsupporting

confidence: 89%

“…As already said in the introduction, low-Pr experiments typically apply copper plates at the top and bottom (e.g. Cioni et al 1997;Horanyi et al 1999;Huang et al 2015;Vasil'ev et al 2015;Zürner et al 2019), which have thermal conductivities that are only an order of magnitude larger than those of the liquid metal (see table 1). The rapid re-establishment of a uniform plate temperature after local plume detachments should ideally proceed by heat conduction inside the plate, and not via the working fluid.…”

Section: Boundary Layer Analysismentioning

confidence: 99%

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Turbulent convection for different thermal boundary conditions at the plates

2020

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Section: Turbulent Heat and Momentum Transportsupporting

confidence: 89%

Section: Boundary Layer Analysismentioning

confidence: 99%

Turbulent convection for different thermal boundary conditions at the plates

2020

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“…Thus, its scaling behaviors are of broad interest and should be considered in future studies. An array of new convection and rotating convection devices have been recently built at research centers worldwide [15,63,107]. These next-generation laboratory devices and associated state-of-the-art numerical simulations, will allow investigations into the efficacy and applicability ranges of the turbulent scaling predictions presented here (Tables I and II).…”

Section: Romentioning

confidence: 99%

Connections between nonrotating, slowly rotating, and rapidly rotating turbulent convection transport scalings

Aurnou

Horn

Julien

2020

Phys. Rev. Research

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In this paper, we investigate and develop scaling laws as a function of external nondimensional control parameters for heat and momentum transport for nonrotating, slowly rotating, and rapidly rotating turbulent convection systems, with the end goal of forging connections and bridging the various gaps between these regimes. Two perspectives are considered, one where turbulent convection is viewed from the standpoint of an applied temperature drop across the domain and the other with a viewpoint in terms of an applied heat flux. While a straightforward transformation exists between the two perspectives, indicating equivalence, it is found the former provides a clear set of connections that bridge between the three regimes. Our generic convection scalings, based upon an inertial-Archimedean balance, produce the classic diffusion-free scalings for the nonrotating limit and the slowly rotating limit. This is characterized by a free-falling fluid parcel on the global scale possessing a thermal anomaly on par with the temperature drop across the domain. In the rapidly rotating limit, the generic convection scalings are based on a Coriolis-inertial-Archimedean (CIA) balance, along with a local fluctuating-mean advective temperature balance. This produces a scenario in which anisotropic fluid parcels attain a thermal wind velocity and where the thermal anomalies are greatly attenuated compared to the total temperature drop. We find that turbulent scalings may be deduced simply by consideration of the generic nondimensional transport parameters-local Reynolds Re = U /ν; local Péclet Pe = U /κ; and Nusselt number Nu = U ϑ/(κ T /H)-through the selection of physically relevant estimates for length , velocity U , and temperature scales ϑ in each regime. Emergent from the scaling analyses is a unified continuum based on a single external control parameter, the convective Rossby number, Ro C = gα T /4 2 H , that strikingly appears in each regime by consideration of the local, convection-scale Rossby number Ro = U/(2). Thus we show that Ro C scales with the local Rossby number Ro in both the slowly rotating and the rapidly rotating regimes, explaining the ubiquity of Ro C in rotating convection studies. We show in non-, slowly, and rapidly rotating systems that the convective heat transport, parametrized via Pe , scales with the total heat transport parameterized via the Nusselt number Nu. Within the rapidly rotating limit, momentum transport arguments generate a scaling for the system-scale Rossby number, Ro H , that, recast in terms of the total heat flux through the system, is shown to be synonymous with the classical flux-based CIA scaling, Ro CIA. These, in turn, are then shown to asymptote to Ro H ∼ Ro CIA ∼ Ro 2 C , demonstrating that these momentum transport scalings are identical in the limit of rapidly rotating turbulent heat transfer.

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“…2016; Zürner et al. 2019); and (iii) high Rayleigh numbers can be achieved even with moderate computational resources; the highest explored in this work has not been achieved in 3-D DNS at this (Scheel & Schumacher 2017). Note that 2-D RBC has been utilized to better understand some of the important phenomena in convection, e.g.…”

Section: Introductionmentioning

confidence: 81%

“…1999; Zürner et al. 2019). On the other hand, numerical investigations of low- convection require massive computational resources, as very small length and time scales need to be resolved accurately to prudently study them (Pandey & Verma 2016; Scheel & Schumacher 2016; Schumacher et al.…”

Section: Introductionmentioning

confidence: 99%