具有中等热力的羽流通过大陆岩石圈上升和在地表喷发的地球动力学过程

Pub Date : 2020-06-20 DOI:10.5800/gt-2020-11-2-0482
A. Kirdyashkin, A. Kirdyashkin, V. Distanov, I. Gladkov
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引用次数: 1

摘要

研究重点为热化学地幔柱,热功率为中等(1.15 < Ka < 1.9)。之前我们已经证明这些羽流是钻石状的。在实验室模拟数据的基础上,描述了羽流管道中熔体的流动结构。地幔柱融化并从核心-地幔边界上升到大陆岩石圈的底部。地幔柱顶板在岩石圈内向上移动,主要是由于地幔柱顶板处岩石圈物质的熔融作用和地幔顶处的超静岩压力作用,使得地幔柱顶板上方的岩石圈块体发生运动。后者表现为地幔柱上方地表的抬升。当火山柱上升穿过岩石圈时,地表的高度增加,直到火山柱上升到临界水平xкр,在那里形成了一个喷发通道。在我们的模型中,烟羽上升速度uпл是烟羽顶部的融化速度。计算了uпл值和超静岩压力U作用下的球形羽顶上升速度。发现了这些速度与羽顶深度之间的关系。得到了地幔柱上方岩石圈块体的动态黏度与地表上升速度的关系。确定了最大地表高度与岩石圈粘度之间的关系。根据不同的时间和不同的岩石圈粘度,确定了海拔高度值。本文介绍了羽流管道/喷发管道界面流动结构的室内模拟结果。(1)在穿过羽流导管和喷发导管轴线的平面上对气流进行了拍摄;(2)垂直于轴向面的线聚焦光束。这些照片被用于测量羽流管道和喷发管道中的流速。确定了相应的雷诺数和流型。在中等强度的羽流中,发现了喷发导管内动压力与羽流导管内动压力的关系。熔体在喷发管道中的流动速度取决于羽顶的超静岩压力、羽管直径和熔体的运动粘度。它的值取决于熔体的不同运动粘度。
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GEODYNAMIC PROCESSES DURING ASCENT OF A PLUME WITH INTERMEDIATE THERMAL POWER THROUGH THE CONTINENTAL LITHOSPHERE AND DURING ITS ERUPTION ON THE SURFACE
The study is focused on thermochemical mantle plumes with intermediate thermal power (1.15 < Ka < 1.9). Previously we have shown that these plumes are diamondiferous. Based on the laboratory modeling data, the flow structure of a melt in a plume conduit is represented. A plume melts out and ascends from the core – mantle boundary to the bottom of the continental lithosphere. The plume roof moves upwards in the lithosphere because of melting of the lithospheric matter at the plume roof and due to the effect of superlithostatic pressure on the roof, which causes motion in the lithosphere block above the plume roof. The latter manifests itself by uplifting of the ground surface above the plume. As the plume ascends through the lithosphere, the elevation of the surface increases until the plume ascends to critical level xкр, where an eruption conduit is formed. In our model, plume ascent velocity uпл is the rate of melting at the plume roof. Values of uпл and the ascent velocity of a spherical plume roof due to superlithostatic pressure U are calculated. Relationships are found between these velocities and the plume roof depth. The dependence of the velocity of the surface’s rise on the dynamic viscosity of the lithosphere block above the plume is obtained. A relationship is determined between the maximum surface elevation and the lithosphere viscosity. The elevation values are determined for different times and different lithosphere viscosities.The results of laboratory modeling of flow structure at the plume conduit/eruption conduit interface are presented. The flow was photographed (1) in the plane passing through the axes of the plume conduit and the eruption conduit; and (2) in case of the line-focus beam perpendicular to the axial plane. The photographs were used for measuring the flow velocities in the plume conduit and the eruption conduit. Corresponding Reynolds numbers and flow regimes are determined. The relation of dynamic pressure in the eruption conduit to that in the plume conduit is found for intermediate-power plumes. The melt flow velocity in the eruption conduit depends on superlithostatic pressure on the plume roof, plume diameter and kinematic viscosity of the melt. Its values are determined for different kinematic viscosities of melt.
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