Sill (geology)

In geology, a sill is a tabular sheet intrusion that has intruded between older layers of sedimentary rock, beds of volcanic lava or tuff, or along the direction of foliation in metamorphic rock. A sill is a concordant intrusive sheet, meaning that a sill does not cut across preexisting rock beds. Stacking of sills builds a sill complex [1] and a large magma chamber at high magma flux.[2] In contrast, a dike is a discordant intrusive sheet, which does cut across older rocks. Sills are fed by dikes,[3] except in unusual locations where they form in nearly vertical beds attached directly to a magma source. The rocks must be brittle and fracture to create the planes along which the magma intrudes the parent rock bodies, whether this occurs along preexisting planes between sedimentary or volcanic beds or weakened planes related to foliation in metamorphic rock. These planes or weakened areas allow the intrusion of a thin sheet-like body of magma paralleling the existing bedding planes, concordant fracture zone, or foliations.

Illustration showing the difference between a dike and a sill.
Salisbury Crags in Edinburgh, Scotland, a sill partially exposed during the Quaternary glaciation
Mid-Carboniferous dolerite sill cutting Lower Carboniferous shales and sandstones, Horton Bluff, Minas Basin South Shore, Nova Scotia

Sills parallel beds (layers) and foliations in the surrounding country rock. They can be originally emplaced in a horizontal orientation, although tectonic processes may cause subsequent rotation of horizontal sills into near vertical orientations. Sills can be confused with solidified lava flows; however, there are several differences between them. Intruded sills will show partial melting and incorporation of the surrounding country rock. On both contact surfaces of the country rock into which the sill has intruded, evidence of heating will be observed (contact metamorphism). Lava flows will show this evidence only on the lower side of the flow. In addition, lava flows will typically show evidence of vesicles (bubbles) where gases escaped into the atmosphere. Because sills generally form at shallow depths (up to many kilometers) below the surface, the pressure of overlying rock prevents this from happening much, if at all. Lava flows will also typically show evidence of weathering on their upper surface, whereas sills, if still covered by country rock, typically do not.

Associated ore deposits

Certain layered intrusions are a variety of sill that often contain important ore deposits. Precambrian examples include the Bushveld, Insizwa and the Great Dyke complexes of southern Africa, the Duluth intrusive complex of the Superior District, and the Stillwater igneous complex of the United States. Phanerozoic examples are usually smaller and include the Rùm peridotite complex[4] of Scotland and the Skaergaard igneous complex of east Greenland. These intrusions often contain concentrations of gold, platinum, chromium and other rare elements.

Transgressive sills

Seismic expression of basaltic sills from the Rockall Trough. Data courtesy UK OGA.

Despite their concordant nature, many large sills change stratigraphic level within the intruded sequence, with each concordant part of the intrusion linked by relatively short dike-like segments. Such sills are known as transgressive, examples include the Whin Sill and sills within the Karoo basin.[5][6] The geometry of large sill complexes in sedimentary basins has become clearer with the availability of 3D seismic reflection data.[7] Such data has shown that many sills have an overall saucer shape and that many others are at least in part transgressive.[8]

See also

References

  1. Leuthold J.; Müntener O.; Baumgartner L.; Putlitz B. (2014). "Petrological constraints on the recycling of mafic crystal mushes and intrusion of braided sills in the Torres del Paine Mafic Complex (Patagonia)". Journal of Petrology. 55 (5): 917–949. Bibcode:2014JPet...55..917L. doi:10.1093/petrology/egu011. hdl:20.500.11850/103136..
  2. Annen C.; Blundy J.D.; Leuthold J.; Sparks R.S.J. (2015). "Construction and evolution of igneous bodies: Towards an integrated perspective of crustal magmatism". Lithos. 230: 206–221. Bibcode:2015Litho.230..206A. doi:10.1016/j.lithos.2015.05.008.
  3. Meade, F. C.; Chew, D. M.; Troll, V. R.; Ellam, R. M.; Page, L. M. (2009-12-01). "Magma Ascent along a Major Terrane Boundary: Crustal Contamination and Magma Mixing at the Drumadoon Intrusive Complex, Isle of Arran, Scotland". Journal of Petrology. 50 (12): 2345–2374. doi:10.1093/petrology/egp081. ISSN 0022-3530.
  4. Emeleus, C. H.; Troll, V. R. (2014-08-01). "The Rum Igneous Centre, Scotland". Mineralogical Magazine. 78 (4): 805–839. doi:10.1180/minmag.2014.078.4.04. ISSN 0026-461X.
  5. Hamilton M.A.; Pearson D.G. (2011). Srivastava R. (ed.). Precise U-Pb Age for the Great Whin Dolerite Complex, N.E. England and Its Significance. Dyke Swarms: Keys for Geodynamic Interpretation. Springer Science & Business Media. ISBN 9783642124969.
  6. Polteau S.; Mazzini A.; Galland O.; Planke S.; Malthe-Sørenssen A. (2008). "Saucer-shaped intrusions: Occurrences, emplacement and implications". Earth and Planetary Science Letters. 266 (1–2): 195–204. Bibcode:2008E&PSL.266..195P. doi:10.1016/j.epsl.2007.11.015.
  7. Thomson K.; Hutton D. (2004). "Geometry and growth of sill complexes: insights using 3D seismic from the North Rockall Trough". Bulletin of Volcanology. 66 (4): 364–375. Bibcode:2004BVol...66..364T. doi:10.1007/s00445-003-0320-z. S2CID 128713713.
  8. Planke S.; Rasmussen T.; Rey S.S.; Myklebust R. (2005). Doré A.G.; Vining B.A. (eds.). Seismic characteristics and distribution of volcanic intrusions and hydrothermal vent complexes in the Vøring and Møre basin. Petroleum geology: north-west Europe and global perspectives : proceedings of the 6th petroleum geology conference held at the Queen Elizabeth II Conference Centre, London 6–9 October 2003. ISBN 9781862391642.
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