The dynamics of an insulating plate over a thermally convecting fluid and its implication for continent movement over convective mantle

Continents exert a thermal blanket effect to the mantle underneath by locally accumulating heat and modifying the flow structures, which in turn affects continent motion. This dynamic feedback is studied numerically with a simplified model of an insulating plate over a thermally convecting fluid wit...

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Bibliographic Details
Published in:Journal of fluid mechanics 2019-06, Vol.868, p.286-315
Main Authors: Mao, Yadan, Zhong, Jin-Qiang, Zhang, Jun
Format: Article
Language:English
Subjects:
Cell size
Computational fluid dynamics
Convection
Convection cells
Coupling
Dynamics
Experiments
Flow structures
Fluid flow
Heating
JFM Papers
Laboratories
Mantle
Mathematical models
Plates (structural members)
Plumes
Prandtl number
Time series
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Summary:Continents exert a thermal blanket effect to the mantle underneath by locally accumulating heat and modifying the flow structures, which in turn affects continent motion. This dynamic feedback is studied numerically with a simplified model of an insulating plate over a thermally convecting fluid with infinite Prandtl number at Rayleigh numbers of the order of $10^{6}$ . Several plate–fluid coupling modes are revealed as the plate size varies. In particular, small plates show long durations of stagnancy over cold downwellings. Between long stagnancies, bursts of velocity are observed when the plate rides on a single convection cell. As plate size increases, the coupled system transitions to another type of short-lived stagnancy, in which case hot plumes develop underneath. For an even larger plate, a unidirectional moving mode emerges as the plate modifies impeding flow structures it encounters while maintaining a single convection cell underneath. These identified modes are reminiscent of some real cases of continent–mantle coupling. Results show that the capability of a plate to overcome impeding flow structures increases with plate size, Rayleigh number and intensity of internal heating. Compared to cases with a fixed plate, cases with a freely drifting plate are associated with higher Nusselt number and more convection cells within the flow domain.
ISSN:0022-1120
1469-7645
DOI:10.1017/jfm.2019.189