Canonical Models of Geophysical and Astrophysical Flows: Turbulent Convection Experiments in Liquid Metals

Ribeiro, Adolfo; Fabre, G.; Guermond, Jean‐Luc; Aurnou, J. M.

doi:10.3390/met5010289

Cited by 16 publications

(20 citation statements)

References 90 publications

(166 reference statements)

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“…We do not include the effects of magnetic fields on convection (cf. Cioni et al 2000;Aurnou & Olson 2001;Stellmach & Hansen 2004;Gillet et al 2007;Hori et al 2010;King & Aurnou 2015;Ribeiro et al 2015). In addition, we use simplified geometries.…”

Section: Introductionmentioning

confidence: 99%

Laboratory-numerical models of rapidly rotating convection in planetary cores

Cheng

Stellmach

Ribeiro

et al. 2015

Geophysical Journal International

110

203

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Section: Introductionmentioning

confidence: 99%

Laboratory-numerical models of rapidly rotating convection in planetary cores

Cheng

Stellmach

Ribeiro

et al. 2015

Geophysical Journal International

110

203

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“…5 In contrast to viscous convection, the problem of inertial convection has received relatively less attention with a relatively small existing literature: Zhang 4,5 first revealed the physical preference of inertial convection in the fluids of small Prandtl number and derived an asymptotic analytical solution for the onset of inertial convection in spherical geometry; Zhang and Roberts 16 extended the spherical analysis to that for a rotating Rayleigh-Bénard layer; Busse and Simitev 6 carried out a numerical study of spherical inertial convection; Aurnou and Olson 17 performed an experimental study of inertial convection in a rotating Rayleigh-Bénard layer using the liquid gallium; and the recent laboratory experiment 18,19 concentrates on the scaling law of strongly turbulent states with (Ra)/(Ra) c ≫ O(10) for the liquid gallium.…”

Section: Introductionmentioning

confidence: 99%

Inertial convection in a rotating narrow annulus: Asymptotic theory and numerical simulation

2015

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An important way of breaking the rotational constraint in rotating convection is to invoke fast oscillation through strong inertial effects which, referring to as inertial convection, is physically realizable when the Prandtl number Pr of rotating fluids is sufficiently small. We investigate, via both analytical and numerical methods, inertial convection in a Boussinesq fluid contained in a narrow annulus rotating rapidly about a vertical symmetry axis and uniformly heated from below, which can be approximately realizable in laboratory experiments [R. P. Davies-Jones and P. A. Gilman, “Convection in a rotating annulus uniformly heated from below,” J. Fluid Mech. 46, 65-81 (1971)]. On the basis of an assumption that inertial convection at leading order is represented by a thermal inertial wave propagating in either prograde or retrograde direction and that buoyancy forces appear at the next order to maintain the wave against the effect of viscous damping, we derive an analytical solution that describes the onset of inertial convection with the non-slip velocity boundary condition. It is found that there always exist two oppositely traveling thermal inertial waves, sustained by convection, that have the same azimuthal wavenumber, the same size of the frequency, and the same critical Rayleigh number but different spatial structure. Linear numerical analysis using a Galerkin spectral method is also carried out, showing a quantitative agreement between the analytical and numerical solutions when the Ekman number is sufficiently small. Nonlinear properties of inertial convection are investigated through direct three-dimensional numerical simulation using a finite-difference method with the Chorin-type projection scheme, concentrating on the liquid metal gallium with the Prandtl number Pr = 0.023. It is found that the interaction of the two counter-traveling thermal inertial waves leads to a time-dependent, spatially complicated, oscillatory convection even in the vicinity of the onset of inertial convection. The nonlinear properties are analyzed via making use of the mathematical completeness of inertial wave modes in a rotating narrow annulus, suggesting that the laminar to weakly turbulent transition is mainly caused by the nonlinear interaction of several inertial wave modes that are excited and maintained by thermal convection at moderately supercritical Rayleigh numbers.

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“…In particular, the study of turbulent convection in liquid metals is getting increasing relevance in the field of Geophysics. This is the topic of the article by Riveiro et al [3]. In this article the authors present experiments at a laboratory scale to benchmark complex hydrodynamics codes with magnetic fields.…”

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confidence: 99%

“…The review of [2] is broad enough, as the work carried out at Grenoble covers almost all interesting matters in the field. Some issues of interest in geophysics and astrophysics are discussed in [3]. The recently discovered liquid-liquid transition in several metals is dealt with in [4].…”

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Some Issues in Liquid Metals Research

Caturla

Jiang

Louis

et al. 2015

Metals

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The ten articles [1][2][3][4][5][6][7][8][9][10] included in this Special Issue on "Liquid Metals" do not intend to comprehensively cover this extensive field, but, rather, to highlight recent discoveries that have greatly broadened the scope of technological applications of these materials. Improvements in understanding the physics of liquid metals are, to a large extent, due to the powerful theoretical tools in the hands of scientists, either semi-empirical [1,5,6] or ab initio (molecular dynamics, see [7]). Surface tension and wetting at metal/ceramic interfaces is an everlasting field of fundamental research with important technological implications. The review of [2] is broad enough, as the work carried out at Grenoble covers almost all interesting matters in the field. Some issues of interest in geophysics and astrophysics are discussed in [3]. The recently discovered liquid-liquid transition in several metals is dealt with in [4]. The fifth contribution [5] discusses the role of icosahedral superclusters in crystallization. In [6], thermodynamic calculations are carried out to identify the regions of the ternary phase diagram of Al-Cu-Y, where the formation of amorphous alloys is most probable. Experimental data and ab initio calculations are presented in [7] to show that an optimal microstructure is obtained if Mg is added to the Al-Si melt before than the modifier AlP alloy. Shock-induced melting of metals by means of laser driven compression is discussed in [8]. With respect to recent discoveries, one of the most outstanding developments is that of gallium alloys that are liquid at room temperature [9], and that, due to the oxide layer that readily cover their surface, maintain some "stiffness". This has opened the possibility of 3D printing with liquid metals. The last article in this Special Issue [10] describes nano-liquid metals, a suspension of liquid metal and its alloy containing nanometer-sized particles. A room-temperature nano-liquid metal and its alloys were first introduced in the area of cooling high heat flux devices, which now is a commercial reality. However, their applications are not only in chip OPEN ACCESS

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Canonical Models of Geophysical and Astrophysical Flows: Turbulent Convection Experiments in Liquid Metals

Cited by 16 publications

References 90 publications

Laboratory-numerical models of rapidly rotating convection in planetary cores

Laboratory-numerical models of rapidly rotating convection in planetary cores

Inertial convection in a rotating narrow annulus: Asymptotic theory and numerical simulation

Some Issues in Liquid Metals Research

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