The Skaergaard Layered Series. Part III. Non-dynamic Layering

doi:10.1093/petroj/38.8.1003

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Journal of Petrology | Volume 38 | Number 8 | Pages 1003-1020 | 1997
© Oxford University Press 1997

The Skaergaard Layered Series. Part III. Non-dynamic Layering

Alan E. Boudreau¹^,* and Alexander R. McBirney²

¹ DEPT. of Geology, Duke University Durham, NC 27708-0227, USA
² DEPT. of Geological Sciences, University of Oregon Eugene, OR 97403, USA

Received May 6, 1996; Revised typescript accepted March 18, 1997

Abstract

Layering in the Skaergaard Intrusion has been divided into twogeneral types, one produced by magmatic flow and another byprocesses resulting from variations of rates of nucleation andcrystallization, and, in the case of the Layered Series, bycompaction-related processes. Modal variations caused by shiftsof cotectic proportions produce thick layers which, in the Layeredand Upper Border Series, are diffuse and normally lack strongfoliation and lineation. In the Marginal Border Series, thelayers are thinner and sharper; possibly because the rate ofaccumulation was slower. Oscillatory nucleation may have playeda role in producing fine-scale cyclic layers, but it was lessimportant than solution and reprecipitation during slow coolingand Ostwald ripening. Evidence for compaction is found in deformedplagioclase laths and a relative deficiency of incompatibleelements in rocks formed on the floor. Layering related to compactionbecomes sharper with increasing height in the Layered Seriesuntil it suddenly disappears above the trough horizon near thebase of Upper Zone b. Mechanical sorting during compaction mayhave produced crude layering, but if it did the evidence haslong since been destroyed by the superimposed effects of solutionand reprecipitation when interstitial liquid rose through theoverlying crystals and re-equilibrated with them. Numericalsimulations illustrate how small differences of surface energycaused by variations of grain size, textural dependence of solubility,and pressure solution can cause segregation of minerals intolayers during solution and reprecipitation.

KEY WORDS: compaction; layering; metasomatism; pressure solution

^* Corresponding author. Telephone: (919) 684-5646. Fax: (919) 684-5833. e-mail: boudreau{at}geo.duke.edu

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