Regime transitions in thermally driven high-Rayleigh number vertical convection

Abstract

Vertical convection is investigated using direct numerical simulations over a wide range of Rayleigh numbers 107 Ra1014 with fixed Prandtl number Pr=10, in a two-dimensional convection cell with unit aspect ratio. It is found that the dependence of the mean vertical centre temperature gradient S on Ra shows three different regimes: In regime I (Ra 5×1010), S is almost independent of Ra; In the newly identified regime II (5×1010 Ra 1013), S first increases with increasing Ra (regime IIa), reaches its maximum and then decreases again (regime IIb); In regime III (Ra1013), S again becomes only weakly dependent on Ra, being slightly smaller than in regime I. The transitions between diffeereent regimes are discussd. In the three different regimes, significantly different flow organizations are identified: In regime I and regime IIa, the location of the maximal horizontal velocity is close to the top and bottom walls; However, in regime IIb and regime III, banded zonal flow structures develop and the maximal horizontal velocity now is in the bulk region. The different flow organizations in the three regimes are also reflected in the scaling exponents in the effective power law scalings Nu Raβ and Re Raγ. In regime I, the fitted scaling exponents (β≈0.26 and γ≈0.51) are in excellent agreement with the theoretical predication of β=1/4 and γ=1/2 for laminar VC (Shishkina, Phys. Rev. E. 2016, 93, 051102). However, in regimes II and III, β increases to a value close to 1/3 and γ decreases to a value close to 4/9. The stronger Ra dependence of Nu is related to the ejection of plumes and larger local heat flux at the walls.