Dougal Jerram

The Field Description of Metamorphic Rocks


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metamorphism progressively increases accordingly until, at temperatures of 600–800 °C (or greater), the rocks themselves begin to melt and we start to enter the realm of igneous petrogenesis. These fields and the main ways in which we classify metamorphic rocks will be discussed in detail in Chapter 3, and as you go along you will see that the P/T of the rocks can be displayed in a variety of diagrammatic forms.

Schematic illustration of the P/T diagram: (a) the classic fields of metamorphism of mafic rocks (the so-called matamorphic facies) in P/T space, and (b) the routes that certain tectonic systems take through the P/T space which give rise to different metamorphic rocks.

      1.3.1 Regional metamorphic rocks

      The most common of the metamorphic styles, regional metamorphism, occurs in zones defined by key pressure and temperature environments found at certain burial depths in the Earth's crust. The regional metamorphic zones are also restricted by certain tectonic settings that are generally related to subduction and continental collision zones, defining two broad groups of regional metamorphic rocks: those related to mountain building events, where two continents collide, and those formed at subduction zone settings where oceanic crust is subducted. As continent–continent collision is preceded by subduction, both styles of regional metamorphism can sometimes be found in the same location, occasionally with strong evidence of high‐pressure, low‐temperature mineral growth in a subduction zone overprinted by higher temperature mineral growth upon and after collision.

      Regional metamorphic zones typically occur due to thickening and/or burial of the crust, so pressure is a very important parameter that drives reactions to progressively change the original rock (protolith) into its different metamorphic types. Certain reactions are strongly pressure‐dependent, and thus the occurrence of specific minerals or mineral assemblages is indicative of ranges of pressure conditions (the most well‐known of which is that diamond typically only forms at pressures greater than the base of normal continental crust). The pressure at which metamorphism occurred is often linked directly with depth, by considering the force applied by the overlying mass of rock. Temperature generally increases with pressure, known as the geothermal gradient (the rate at which temperature increases with depth), but the specifics of this gradient can vary dramatically with tectonic setting. Again, there is generally a mineralogical response to changing temperature, so unravelling the metamorphic history of a series of outcrops in the field can yield important information about the style of regional metamorphism and, thus, tectonic setting and evolution.

upper C h l o r i t e greater-than upper B i o t i t e greater-than upper G a r n e t greater-than upper S t a u r o l i t e greater-than upper K y a n i t e greater-than upper S i l limit a n t e greater-than upper M e l t Schematic illustration of the classic Barrovian Zones of regional metamorphism first described from Scotland.

      This mineralogical change with increasing grade would be mirrored in a maturation of the rock texture as follows:

upper S e d i m e n t a r y upper R o c k greater-than upper S h a l e greater-than upper S l a t e greater-than upper P h y l l i t e greater-than upper S c h i s t greater-than upper G n e i s s greater-than upper M i g m a t i t e

      If the starting material was an igneous rock, such as basalt, the sequence would be:

upper B a s a l t greater-than upper G r e e n s c h i s t greater-than upper A m b i b o l i t e greater-than upper G r a n u l i t e