Earth:Laccolith

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Short description: Mass of igneous rock formed from magma


Cross section of a laccolith intruding into and deforming strata

A laccolith is a body of intrusive rock with a dome-shaped upper surface and a level base, fed by a conduit from below. A laccolith forms when magma (molten rock) rising through the Earth's crust begins to spread out horizontally, prying apart the host rock strata. The pressure of the magma is high enough that the overlying strata are forced upward, giving the laccolith its dome-like form.

Over time, erosion can expose the solidified laccolith, which is typically more resistant to weathering than the host rock. The exposed laccolith then forms a hill or mountain. The Henry Mountains of Utah, US, are an example of a mountain range composed of exposed laccoliths. It was here that geologist Grove Karl Gilbert carried out pioneering field work on this type of intrusion. Laccolith mountains have since been identified in many other parts of the world.

Basic types of intrusions:
1. Laccolith
2. Small dike
3. Batholith
4. Dike
5. Sill
6. Volcanic neck, pipe
7. Lopolith
Note: As a general rule, in contrast to the smoldering volcanic vent in the figure, these names refer to the fully cooled and usually millions-of-years-old rock formations, which are the result of the underground magmatic activity shown.

Description

A laccolith is a type of igneous intrusion, formed when magma forces its way upwards through the Earth's crust but cools and solidifies before reaching the surface. Laccoliths are distinguished from other igneous intrusions by their dome-shaped upper surface and level base. They are assumed to be fed by a conduit from below, though this is rarely exposed.[1][2] When the host rock is volcanic, the laccolith is referred to as a cryptodome.[3] Laccoliths form only at relatively shallow depth in the crust,[4] usually from intermediate composition magma, though laccoliths of all compositions from silica-poor basalt to silica-rich rhyolite are known.[5]

A laccolith forms after an initial sheet-like intrusion has been injected between layers of sedimentary rock. If the intrusion remains limited in size, it forms a sill, in which the strata above and below the intrusion remain parallel to each other and the intrusion remains sheetlike. The intrusion begins to lift and dome the overlying strata only if the radius of the intrusion exceeds a critical radius, which is roughly:[6]

[math]\displaystyle{ r \ge \frac{2T\tau}{P_m-P_l} }[/math]

where [math]\displaystyle{ P_m }[/math] is the pressure of the magma, [math]\displaystyle{ P_l }[/math] is the lithostatic pressure (weight of the overlying rock), [math]\displaystyle{ T }[/math] is the thickness of the overlying rocks, and [math]\displaystyle{ \tau }[/math] is the shear strength of the overlying rock. For example, in the Henry Mountains of Utah, US, the geologist Grove Karl Gilbert found in 1877 that sills were always less than 1 square kilometer (0.4 sq mi) in area while laccoliths were always greater than 1 square kilometer in area. From this, Gilbert concluded that sills were forerunners of laccoliths. Laccoliths formed from sills only when they became large enough for the pressure of the magma to force the overlying strata to dome upwards. Gilbert also determined that larger laccoliths formed at greater depth.[1] Both laccoliths and sills are classified as concordant intrusions, since the bulk of the intrusion does not cut across host rock strata, but intrudes between strata.[7]

More recent study of laccoliths has confirmed Gilbert's basic conclusions, while refining the details. Both sills and laccoliths have blunt rather than wedgelike edges, and sills of the Henry Mountains are typically up to 10 meters (33 ft) thick while laccoliths are up to 200 meters (660 ft) thick.[8] The periphery of a laccolith may be smooth, but it may also have fingerlike projections consistent with Rayleigh-Taylor instability of the magma pushing along the strata.[9] An example of a fingered laccolith is the Shonkin Sag laccolith in Montana, US.[4] The critical radius for the sill to laccolith transition is now thought to be affected the viscosity of the magma (being greater for less viscous magma) as well as the strength of the host rock. A modern formula for the shape of a laccolith is:

Idealized laccolith shape
[math]\displaystyle{ z = \frac{3(P_m-\rho_cgT)}{16BT^3}(r_0^2-r^2)^2 }[/math]

where [math]\displaystyle{ z }[/math] is the height of the laccolith roof, [math]\displaystyle{ g }[/math] is the acceleration of gravity, [math]\displaystyle{ B }[/math] is the elastic modulus of the host rock, [math]\displaystyle{ r }[/math] is the horizontal distance from the center of the laccolith, and [math]\displaystyle{ r_0 }[/math] is the outer radius of the laccolith.[4] Because of their greater thickness, which slows the cooling rate, the rock of laccoliths is usually coarser-grained than the rock of sills.[5]

The growth of laccoliths can take as little as a few months when associated with a single magma injection event,[10][11] or up to hundreds or thousands of years by multiple magmatic pulses stacking sills on top of each other and deforming the host rock incrementally.[12]

Over time, erosion can form small hills and even mountains around a central peak since the intrusive rock is usually more resistant to weathering than the host rock.[13] Because the emplacement of the laccolith domes up the overlying beds, local topographic relief is increased and erosion is accelerated, so that the overlying beds are eroded away to expose the intrusive cores.[14]

Etymology

The term was first applied as laccolite by Gilbert after his study of intrusions of diorite in the Henry Mountains of Utah in about 1875.[15][16] The word laccolith was derived in 1875–1880, from Greek lákko(s) 'pond' plus -lith 'stone'.[17]

Where laccoliths form

Laccoliths tend to form at relatively shallow depths and in some cases are formed by relatively viscous magmas, such as those that crystallize to diorite, granodiorite, and granite. In those cases cooling underground may take place slowly, giving time for larger crystals to form in the cooling magma. In other cases less viscous magma such as shonkinite may form phenocrysts of augite at depth, then inject through a vertical feeder dike that ends in a laccolith.[18]

Sheet intrusions tend to form perpendicular to the direction of least stress in the country rock they intrude. Thus laccoliths are characteristic of regions where the crust is being compressed and the direction of least stress is vertical, while areas where the crust is in tension are more likely to form dikes, since the direction of least stress is then horizontal. For example, the laccoliths of the Ortiz porphyry belt in New Mexico likely formed during Laramide compression of the region 33 to 36 million years ago. When Laramide compression was later replaced by extension, emplacement of sills and laccoliths was replaced by emplacement of dikes. Dating of the intrusions has helped determine the point in geologic time when compression was replaced with extension.[19]

Examples

In addition to the Henry Mountains, laccolith mountains are found on the nearby Colorado Plateau in the La Sal Mountains and Abajo Mountains.[14]

The filled and solidified magma chamber of Torres del Paine (Patagonia) is one of the best exposed laccoliths, built up incrementally by horizontal granitic and mafic magma intrusions over 162 ± 11 thousand years.[20] Horizontal sheeted intrusions were fed by vertical intrusions.[21]

The small Barber Hill syenite-stock laccolith in Charlotte, Vermont, has several volcanic trachyte dikes associated with it. Molybdenite is also visible in outcrops on this exposed laccolith. In Big Bend Ranch State Park, at the southwesternmost visible extent of the Ouachita orogeny, lies the Solitario.[22] It consists of the eroded remains of a laccolith, presumably named for the sense of solitude that observers within the structure might have, due to the partial illusion of endless expanse in all directions.[22]

One of the largest laccoliths in the United States is Pine Valley Mountain in the Pine Valley Mountain Wilderness area near St. George, Utah.[23]

A system of laccoliths is exposed on the Italian island of Elba, which form a "Christmas tree" laccolith system in which a single igneous plumbing system has produced multiple laccoliths at different levels in the crust.[24]

Problems reconstructing shapes of intrusions

The original shape of intrusions can be difficult to reconstruct. For instance, Devils Tower in Wyoming and Needle Rock in Colorado were both thought to be volcanic necks, but further study has suggested they are eroded laccoliths.[25][26] At Devils Tower, intrusion would have had to cool very slowly so as to form the slender pencil-shaped columns of phonolite porphyry seen today. However, erosion has stripped away the overlying and surrounding rock, so it is impossible to reconstruct the original shape of the igneous intrusion, which may or may not be the remnant of a laccolith. At other localities, such as in the Henry Mountains and other isolated mountain ranges of the Colorado Plateau, some intrusions demonstrably have the classic shapes of laccoliths.[27]

Extraterrestrial laccoliths

There are many examples of possible laccoliths on the surface of the Moon. Some are centered in impact craters and may form as part of the post-impact evolution of the crater.[28] Others are located along possible faults or fissures.[29] Laccoliths on the Moon are much wider but less thick than those on Earth, due to the Moon's lower gravity and more fluid magmatism.[30]

Possible laccoliths have also been identified on Mars, in western Arcadia Planitia.[31]

Gallery

  • Dolerite intrusion laccolith in Sydney, Australia

  • Laccolith exposed by erosion of overlying strata in Montana

  • Pink monzonite laccolith intrudes within the grey Cambrian and Ordovician strata near Notch Peak, Utah[32]

  • The eroded laccolith on the top of Vitosha[33] - the domed mountain next to Sofia, Bulgaria

See also

References

  1. 1.0 1.1 Philpotts, Anthony R.; Ague, Jay J. (2009). Principles of igneous and metamorphic petrology (2nd ed.). Cambridge, UK: Cambridge University Press. pp. 93–94. ISBN 9780521880060. 
  2. Leong, Goh Cheng (1995-10-27) (in en). Certificate Physics And Human Geography; Indian Edition. Oxford University Press. pp. 20. ISBN 978-0-19-562816-6. https://books.google.com/books?id=XhJ4RAAACAAJ&q=certificate+physical+and+human+geography. 
  3. Burchardt, Steffi; Mattsson, Tobias; Palma, J. Octavio; Galland, Olivier; Almqvist, Bjarne; Mair, Karen; Jerram, Dougal A.; Hammer, Øyvind et al. (2019-08-14). "Progressive Growth of the Cerro Bayo Cryptodome, Chachahuén Volcano, Argentina—Implications for Viscous Magma Emplacement". Journal of Geophysical Research: Solid Earth 124 (8): 7934–7961. doi:10.1029/2019JB017543. ISSN 2169-9313. Bibcode2019JGRB..124.7934B. 
  4. 4.0 4.1 4.2 Philpotts & Ague 2009, p. 95.
  5. 5.0 5.1 Philpotts & Ague 2009, p. 94.
  6. Philpotts & Ague 2009, equation 4.4, p.94.
  7. Philpotts & Ague 2009, pp. 79-80.
  8. Johnson, Arvid M.; Pollard, David D. (July 1973). "Mechanics of growth of some laccolithic intrusions in the Henry mountains, Utah, I". Tectonophysics 18 (3–4): 261–309. doi:10.1016/0040-1951(73)90050-4. 
  9. Pollard, David D.; Muller, Otto H.; Dockstader, David R. (1 March 1975). "The Form and Growth of Fingered Sheet Intrusions". GSA Bulletin 86 (3): 351–363. doi:10.1130/0016-7606(1975)86<351:TFAGOF>2.0.CO;2. Bibcode1975GSAB...86..351P. 
  10. Castro, Jonathan M.; Cordonnier, Benoit; Schipper, C. Ian; Tuffen, Hugh; Baumann, Tobias S.; Feisel, Yves (December 2016). "Rapid laccolith intrusion driven by explosive volcanic eruption". Nature Communications 7 (1): 13585. doi:10.1038/ncomms13585. ISSN 2041-1723. PMID 27876800. Bibcode2016NatCo...713585C. 
  11. Mattsson, Tobias; Burchardt, Steffi; Almqvist, Bjarne S. G.; Ronchin, Erika (2018-02-05). "Syn-Emplacement Fracturing in the Sandfell Laccolith, Eastern Iceland—Implications for Rhyolite Intrusion Growth and Volcanic Hazards". Frontiers in Earth Science 6: 5. doi:10.3389/feart.2018.00005. ISSN 2296-6463. Bibcode2018FrEaS...6....5M. 
  12. Morgan, Sven; Stanik, Amy; Horsman, Eric; Tikoff, Basil; de Saint Blanquat, Michel; Habert, Guillaume (April 2008). "Emplacement of multiple magma sheets and wall rock deformation: Trachyte Mesa intrusion, Henry Mountains, Utah". Journal of Structural Geology 30 (4): 491–512. doi:10.1016/j.jsg.2008.01.005. Bibcode2008JSG....30..491M. 
  13. Fillmore, Robert (2010). Geological evolution of the Colorado Plateau of eastern Utah and western Colorado, including the San Juan River, Natural Bridges, Canyonlands, Arches, and the Book Cliffs. Salt Lake City: University of Utah Press. pp. 288–289. ISBN 9781607810049. 
  14. 14.0 14.1 Fillmore 2010, pp. 292-293.
  15. Gilbert, G.K. (1877). "Geology of the Henry Mountains". Monograph. Washington, D.C.. pp. i-160. doi:10.3133/70038096. http://pubs.er.usgs.gov/publication/70038096. 
  16. Aber, James S.. "Grove Karl Gilbert". academic.emporia.edu. http://academic.emporia.edu/aberjame/histgeol/gilbert/gilbert.htm. 
  17. "laccolith". dictionary.com. https://www.dictionary.com/browse/laccolith. 
  18. "Beall, Joseph J." "Pseudo-Rhythmic Layering in the Square Butte Alkali-Gabbro Laccolith." American Mineralogist. 57:7-8 (July–August 1972).
  19. Maynard, Steven R. (February 2005). "Laccoliths of the Ortiz porphyry belt, Santa Fe County, New Mexico". New Mexico Geology 27 (1). https://geoinfo.nmt.edu/publications/periodicals/nmg/27/n1/nmg_v27_n1_p3.pdf. Retrieved 8 June 2020. 
  20. Leuthold, Julien; Müntener, Othmar; Baumgartner, Lukas; Putlitz, Benita; Ovtcharova, Maria; Schaltegger, Urs (2012). "Time resolved construction of a bimodal laccolith (Torres del Paine, Patagonia)". Earth and Planetary Science Letters 325–326: 85–92. doi:10.1016/j.epsl.2012.01.032. Bibcode2012E&PSL.325...85L. 
  21. Leuthold, Julien; Müntener, Othmar; Baumgartner, Lukas; Putlitz, Benita (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. doi:10.1093/petrology/egu011. Bibcode2014JPet...55..917L. http://doc.rero.ch/record/291091/files/egu011.pdf. 
  22. 22.0 22.1 Spearing, Darwin. Roadside Geology of Texas. 1991. Mountain Press Publishing Company. ISBN:978-0-87842-265-4.
  23. Cook, E.F. (1957). "Geology of the Pine Valley Mountains Utah". Utah Geological and Mineralogical Studies (58): 1–111. 
  24. Rocchi, Sergio; Westerman, David S.; Dini, Andrea; Innocenti, Fabrizio; Tonarini, Sonia (1 November 2002). "Two-stage growth of laccoliths at Elba Island, Italy". Geology 30 (11): 983–986. doi:10.1130/0091-7613(2002)030<0983:TSGOLA>2.0.CO;2. Bibcode2002Geo....30..983R. 
  25. Vitaliano, Dorothy B. "Geomythology: geological origins of myths and legends" in Myth and Geology, ed. L. Piccardi and W. B. Masse, p. 1. Geological Society of London. ISBN:978-1-86239-216-8
  26. "Noe, D. C., and Alexander T. Klink. OF-15-06 Geologic Map of the Crawford Quadrangle, Delta and Montrose Counties, Colorado. 1:24,000.". Colorado Geological Survey. https://store.coloradogeologicalsurvey.org/product/geologic-map-crawford-quadrangle-delta-montrose-colorado/. 
  27. Jackson, Marie D.; Pollard, David D. (1 January 1988). "The laccolith-stock controversy: New results from the southern Henry Mountains, Utah". GSA Bulletin 100 (1): 117–139. doi:10.1130/0016-7606(1988)100<0117:TLSCNR>2.3.CO;2. Bibcode1988GSAB..100..117J. 
  28. Wichman, R.W. and Schultz, P. H. (1996) Crater-Centered Laccoliths on the Moon: Modeling Intrusion Depth and Magmatic Pressure at the Crater Taruntius, Icarus, Volume 122, Issue 1, July 1996, pages 193-199. doi:10.1006/icar.1996.0118
  29. Wöhler, Christian; Lena, Raffaello (December 2009). "Lunar intrusive domes: Morphometric analysis and laccolith modelling". Icarus 204 (2): 381–398. doi:10.1016/j.icarus.2009.07.031. Bibcode2009Icar..204..381W. 
  30. Michaut, Chloé (17 May 2011). "Dynamics of magmatic intrusions in the upper crust: Theory and applications to laccoliths on Earth and the Moon". Journal of Geophysical Research 116 (B5): B05205. doi:10.1029/2010JB008108. Bibcode2011JGRB..116.5205M. https://hal-insu.archives-ouvertes.fr/insu-03606481/file/Journal%20of%20Geophysical%20Research%20Solid%20Earth%20-%202011%20-%20Michaut%20-%20Dynamics%20of%20magmatic%20intrusions%20in%20the%20upper%20crust%20Theory.pdf. 
  31. Michaut, Chloé; Baratoux, David; Thorey, Clément (July 2013). "Magmatic intrusions and deglaciation at mid-latitude in the northern plains of Mars". Icarus 225 (1): 602–613. doi:10.1016/j.icarus.2013.04.015. Bibcode2013Icar..225..602M. 
  32. Nabelek, Peter I. (2007). "Fluid evolution and kinetics of metamorphic reactions in calc-silicate contact aureoles—From H2O to CO2 and back". Geology 35 (10): 927. doi:10.1130/G24051A.1. Bibcode2007Geo....35..927N. 
  33. Georgiev, N.; Henry, B.; Jordanova, N.; Jordanova, D.; Naydenov, K. (2014). "Emplacement and fabric-forming conditions of plutons from structural and magnetic fabric analysis: A case study of the Plana pluton (Central Bulgaria)". Tectonophysics 629: 138–154. doi:10.1016/j.tecto.2014.02.018. Bibcode2014Tectp.629..138G. 

Further reading

  • Blatt, Harvey; Tracy, Robert J. (1996). Petrology : igneous, sedimentary, and metamorphic. (2nd ed.). New York: W.H. Freeman. pp. 13–15. ISBN 0-7167-2438-3. 
  • "Laccolith Complexes of Southeastern Utah: Time of Emplacement and Tectonic Setting — Workshop Proceedings". United States Geological Survey Bulletin 2158. 1998. doi:10.3133/B2158. 
  • Hyndman, D. W.; Alt, D. (November 1987). "Radial Dikes, Laccoliths, and Gelatin Models". The Journal of Geology 95 (6): 763–774. doi:10.1086/629176. Bibcode1987JG.....95..763H. 

External links



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