The Comparison of Newtonian and Non-Newtonian Rheology Cases of the Solution of 2D Hydrodynamic Equations in the Boussinesq Approximation: A Mechanism of Upwelling Convective Flow Transporting Hydrocarbons

Journal of applied mechanical engineering Pub Date : 2019-01-01 DOI:10.35248/2168-9873.19.8.314

A. Kharitonov, S. Gavrilov

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Abstract

Thermo-mechanical model of the mantle wedge between the base of the overlying Scythian lithospheric plate and the upper surface of the Black Sea micro-plate subducting under the Scythian one with a velocity V at an angle β is obtained for the infinite Prandtl number fluid as a solution of non-dimensional 2D hydrodynamic equations in the Boussinesq approximation. For both Newtonian and non-Newtonian rheology cases 2D thermal viscous dissipationdriven convection mechanism in the mantle wedge above the Black Sea micro-plate subducting under the Crimea peninsula is modelled numerically. The effects of 410 km and 660 km phase transitions are taken into account. In the case of Newtonian rheology, the upwelling convective flow transporting heat to the Earth’s surface locates at far greater distance from the trench than they observed 2D heat flux anomaly. In the case of non-Newtonian rheology, the upwelling convective flow transporting heat to the Earth’s surface locates at twice greater distance from the trench than they observed 2D heat flux anomaly, the velocity in the convective vortices being over ∼10 m per year.

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二维流体动力学方程在Boussinesq近似下的牛顿和非牛顿流变解的比较:上升流对流输送碳氢化合物的机制

对于无限普朗特数流体，用Boussinesq近似法求解二维无量纲流体力学方程，得到了上覆斯基泰岩石圈板块基底与俯冲于斯基泰板块之下的黑海微板块上表面之间以速度V角β的地幔楔的热力学模型。对克里米亚半岛下黑海微板块俯冲过程中地幔楔块的二维热粘性耗散驱动对流机制进行了数值模拟。考虑了410 km和660 km相变的影响。在牛顿流变性的情况下，向地球表面输送热量的上升流位于距离海沟远比他们观察到的二维热流异常。在非牛顿流变性的情况下，向地球表面输送热量的上升流与海沟的距离比观测到的二维热通量异常大两倍，对流涡旋的速度每年超过10米。

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Journal of applied mechanical engineering

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