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Origin, structure and deformation of low-magmatic oceanic lithosphere in the vicinity of ODP Leg 209, Mid-Atlantic Ridge 14oN - 16oN.

大西洋中脊 14oN - 16oN ODP Leg 209 附近低岩浆大洋岩石圈的起源、结构和变形。

基本信息

批准号：
NE/B500058/1
负责人：
Roger Clive Searle
金额：
$ 6.81万
依托单位：
Durham University
依托单位国家：
英国
项目类别：
Research Grant
财政年份：
2007
资助国家：
英国
起止时间：
2007 至无数据
项目状态：
已结题

来源：
https://gtr.ukri.org/projects?ref=NE%2FB500058%2F1
关键词：
Origin structure deformation low magmatic

项目摘要

When tectonic plates separate, the peridotite rock in the Earth's upper mantle rises and melts, then the melt cools to form oceanic crust. Generally this crust is 6-7 km thick, but in some areas it is much thinner and may be missing altogether. Such a situation occurs around the Fifteen Twenty Fracture Zone on the Mid-Atlantic Ridge. Here, peridotite crops out extensively for tens of kilometres along the ridge axis, in zones marked by complex topography and faulting. This provides a superb opportunity to study both rocks from the mantle, and the processes by which seafloor spreading takes place in the absence of substantial melt or a thick crust. The ocean drilling programme has already drilled eight deep holes in the area, and we will complement that work with very detailed mapping and taking many more shallow samples. We will image the seafloor using sonar, and use this to map the faults and different rock types. We will then choose sites where we will take up to 60 shallow cores of rock. These samples will be oriented in space, allowing us to determine properties such as the directions of flow, stretching and fracturing as the mantle rocks were emplaced, and subsequent rotations by faulting. Chemical analysis will enable us to unravel details of where these rocks originated and how they melted and subsequently evolved.

当构造板块分离时，地球上地幔中的橄榄岩上升并熔化，然后熔化物冷却形成海洋地壳。一般来说，这种地壳厚6-7公里，但在某些地区，它要薄得多，甚至可能完全消失。这种情况发生在大西洋中脊的1520断裂带周围。在这里，橄榄岩沿着山脊轴线沿着数十公里的范围内广泛地出露，这些区域以复杂的地形和断层为标志。这提供了一个极好的机会来研究来自地幔的岩石，以及在没有大量熔融或厚地壳的情况下海底扩张发生的过程。海洋钻探方案已经在该地区钻了八个深孔，我们将以非常详细的测绘和采集更多的浅层样本来补充这项工作。我们将使用声纳对海底进行成像，并使用它来绘制断层和不同岩石类型的地图。然后，我们将选择我们将采取多达60个浅岩芯的地点。这些样品将在空间中定向，使我们能够确定地幔岩石就位时的流动方向、拉伸和断裂以及随后的断层旋转等性质。化学分析将使我们能够揭开这些岩石起源的细节，以及它们如何熔化和随后演变。