Jump rope vortex flow in liquid metal Rayleigh–Bénard convection in a cuboid container of aspect ratio

Abstract: We study the topology and the temporal dynamics of turbulent Rayleigh–Bénard convection in a liquid metal with a Prandtl number of 0.03 located inside a box with a square base area and an aspect ratio of $\varGamma = 5$ . Experiments and numerical simulations are focused on the Rayleigh number range $6.7 \times 10^{4} \leqslant Ra \leqslant 3.5 \times 10^{5}$ , where a new cellular flow regime has been reported previously (Akashi et al., Phys. Rev. Fluids, … Show more

“…The RC wall mode frequency is fp,SW = 10, in good agreement with theory (dashed green vertical line (Zhang & Liao 2009)). The central sensor spectrum peaks at fp,0 90, near the predicted frequency for oscillatory inertial convection (dashed blue vertical line (Zhang & Liao 2009)) and in good agreement with the thermovelocimetric RC measurements of Vogt et al (2021). The S 2/3 sensor contains both longer-period thermal oscillations due to the wall modes and shorter-period content due to the inertial bulk oscillations, revealing the multi-modal nature of low-Pr RC flows.…”

“…2018; Akashi et al. 2021; Horn, Schmid & Aurnou 2021). The spectral peaks in figure 3( b ) agree within 0.7 % of the JRV overturn frequency prediction of Vogt et al.…”

Experimental pub crawl from Rayleigh–Bénard to magnetostrophic convection

“…The RC wall mode frequency is fp,SW = 10, in good agreement with theory (dashed green vertical line (Zhang & Liao 2009)). The central sensor spectrum peaks at fp,0 90, near the predicted frequency for oscillatory inertial convection (dashed blue vertical line (Zhang & Liao 2009)) and in good agreement with the thermovelocimetric RC measurements of Vogt et al (2021). The S 2/3 sensor contains both longer-period thermal oscillations due to the wall modes and shorter-period content due to the inertial bulk oscillations, revealing the multi-modal nature of low-Pr RC flows.…”

“…2018; Akashi et al. 2021; Horn, Schmid & Aurnou 2021). The spectral peaks in figure 3( b ) agree within 0.7 % of the JRV overturn frequency prediction of Vogt et al.…”

Experimental pub crawl from Rayleigh–Bénard to magnetostrophic convection

“…For larger convection tanks, multiple circulations exist. In a Γ = 5 Cartesian cell, the dynamics is also dominated by JRVs, in this case four separate vortices [31]. Pandey et al [9] defined superstructures in RBC as coherent turbulent flow structure whose horizontal length-scale is greater than the height of the fluid layer.…”

“…Direct numerical simulations (DNS) have complemented these efforts. The three most prominent LSC modes are torsional oscillations [7], sloshing [8,29], and jump rope vortices (JRVs) [30,31], all of which have frequencies of the order of the turnover frequency. The quasi-2D sloshing and torsional (ST) modes dominate in enclosures with diameter-to-height aspect ratios of Γ = D/H 1 [32], whereas 3D JRVs dominate for Γ √ 2 [30].…”

“…-In the following, we will briefly present the traditional analysis methods to detect torsional oscillations, sloshing, and JRVs for the sake of completeness and to facilitate comparison with the DMD results. Shadowgraphs [7], PIV [8], and UDV [30,31] are means of diagnosing the interior flow in experiments. However, the arguably most convenient and straightforward method for identifying signatures of the different LSC dynamics are thermal measurements acquired along the circumference, at midheight, z = H/2, and in the lower and upper part of the cylinder, especially at H/4 and 3H/4 [8,29,35,46].…”

Unravelling the large-scale circulation modes in turbulent Rayleigh-Bénard convection ^(a)

A review on Rayleigh-Bénard convection influenced by the complicating factors