Granitic batholiths: from pervasive and continuous melting in the lower crust to discontinuous and spaced plutonism in the upper crust

Transactions of the Royal Society of Edinburgh: earth sciences Pub Date : 2006-12-01 DOI:10.1017/S0263593300001474

J. Vigneresse

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引用次数: 40

Abstract

ABSTRACT The generation of granitic magmas begins with melting in the lower crust, under active participation of the underlying mantle. Thermally driven, melting is a pervasive and continuous process that develops over a wide region. In contrast, the building of a granitic pluton is highly discontinuous in time and space. Several inputs of magma, sometimes with a different chemical compositions, are focused toward a region where they accumulate, forming a large pluton, often separated by some 50 km from an adjacent one. The switch from a continuous to a discontinuous process represents a fundamental point of magma generation. It gives place to the modified model m(M-SAE), in which the mantle (m) and Melting (M) are separated from the Segregation (S), Ascent (A) and Emplacement (E) modes. Discontinuities result from non-linear processes that develop during segregation and ascent of the magma. They rely on the non-linear rheology of partially molten rocks. Thresholds control the change from a solid-like to liquid-like behaviour of the magma. In between, the rheology exhibits sudden jumps between states. Because two phases continuously coexist (matrix and melt), strain is highly partitioned between them. This may induce highly discontinuous melt segregation, which needs both pure and simple shear to develop. Melt focusing is controlled by the viscosity contrast between the two phases. It gives rise to different compaction lengths depending on the region, a partially melting source or a nearly brittle crust, where it develops. Because ascent and emplacement are discontinuous in time, this allows the crust to relax, avoiding the room problem for a pluton intruding the upper crust. Intermediate magma chambers could develop with different temperature and magma composition. They could be the place of enhanced magma mixing. Finally, the stress conditions, which differ for each tectonic setting, influence the shape of the granitic body.

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花岗质岩基:从下地壳的普遍连续熔融到上地壳的不连续间隔深岩浆作用

花岗岩岩浆的形成始于下地壳的熔融，下地幔的积极参与。在热驱动下，融化是一个普遍和持续的过程，在一个广泛的地区发展。而花岗岩岩体的构造在时间和空间上具有高度的不连续性。岩浆的几个输入，有时具有不同的化学成分，聚集在一个区域，形成一个大的岩体，通常与相邻的岩体相隔约50公里。从连续过程到不连续过程的转换是岩浆生成的一个基本点。它取代了修正模型m(m - sae)，其中地幔(m)和熔融(m)与隔离(S)，上升(A)和就位(E)模式分离。不连续是岩浆分离和上升过程中非线性过程的结果。它们依赖于部分熔融岩石的非线性流变性。阈值控制着岩浆从固态到液态的变化。在两者之间，流变学表现出状态之间的突然跳跃。由于两相(基体和熔体)连续共存，应变在它们之间高度分割。这可能引起高度不连续的熔体偏析，需要纯剪切和简单剪切来发展。熔体聚焦由两相之间的粘度对比来控制。它会产生不同的压实长度，这取决于它所发育的区域，是部分熔融的源还是近乎脆性的地壳。由于上升和侵位在时间上是不连续的，这使得地壳松弛，避免了深部侵入上地壳的空间问题。在不同的温度和岩浆成分条件下，中间岩浆房可能发育。它们可能是岩浆混合增强的地方。最后，不同构造环境的应力条件对花岗岩体的形状有影响。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Transactions of the Royal Society of Edinburgh: earth sciences

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