Oscillatory large-scale circulation in liquid-metal thermal convection and its structural unit

Abstract

In Rayleigh-B\'enard convection (RBC), the size of a flow domain and its aspect ratio (a ratio between the spatial length and height of the domain) affect the shape of the large-scale circulation (LSC). For some aspect ratios, the flow dynamics include a three-dimensional oscillatory mode known as a jump-rope vortex (JRV), however, the effects of varying aspect ratios on this mode are not well investigated. In this paper, we study these aspect-ratio effects in liquid metals, for a low Prandtl number Pr=0.03. Direct numerical simulations and experiments are carried out for a Rayleigh number range 2.9 × 104 ≤ Ra ≤ 1.6 × 106 and square cuboid domains with =2, 2.5, 3 and 5. Our study demonstrates that a repeating pattern of a JRV encountered at an aspect ratio ≈ 2.5 is the basic structural unit that builds up to a lattice of interlaced JRVs at the largest aspect ratio. The size of the domain determines how many structural units are self-organized within the domain; the number of the realized units is expected to scale as 2 with sufficiently large and growing . We find the oscillatory modes for all investigated , however, they are more pronounced for =2.5 and =5. Future studies for large-aspect ratio domains of different shapes would enhance our understanding of how the JRVs adjust and reorganize at such scaled-up geometries, and answer the question of whether they are indeed the smallest superstructure units.