Anticline






Cross-sectional diagram of an anticline




Anticline exposed in road cut (small syncline visible at far right). Note the man standing in front of the formation, for scale. New Jersey, U.S.A.


In structural geology, an anticline is a type of fold that is an arch-like shape and has its oldest beds at its core. A typical anticline is convex up in which the hinge or crest is the location where the curvature is greatest, and the limbs are the sides of the fold that dip away from the hinge. Anticlines can be recognized and differentiated from antiforms by a sequence of rock layers that become progressively older toward the center of the fold. Therefore, if age relationships between various rock strata are unknown, the term antiform should be used.


The progressing age of the rock strata towards the core and uplifted center, are the trademark indications for evidence of anticlines on a geologic map. These formations occur because anticlinal ridges typically develop above thrust faults during crustal deformations. The uplifted core of the fold causes compression of strata that preferentially erodes to a deeper stratigraphic level relative to the topographically lower flanks. Motion along the fault including both shortening and extension of tectonic plates, usually also deforms strata near the fault. This can result in an asymmetrical or overturned fold.[1]




Contents





  • 1 Terminology of different folds


  • 2 Formation processes


  • 3 Economic significance


  • 4 Notable examples

    • 4.1 Asia


    • 4.2 Australia


    • 4.3 Europe


    • 4.4 North America



  • 5 Gallery


  • 6 See also


  • 7 References


  • 8 Bibliography




Terminology of different folds




Diagram showing constituent parts of an anticline


An antiform can be used to describe any fold that is convex up. It is the relative ages of the rock strata that distinguish anticlines from antiforms. The hinge of an anticline refers to the location where the curvature is greatest, also called the crest.[1] The hinge is also the highest point on a stratum along the top of the fold. The culmination also refers to the highest point along any geologic structure. The limbs are the sides of the fold that display less curvature. The inflection point is the area on the limbs where the curvature changes direction.[2]


The axial surface is an imaginary plane connecting the hinge of each layer of rock stratum through the cross section of an anticline. If the axial surface is vertical and the angles on each side of the fold are equivalent, then the anticline is symmetrical. If the axial plane is tilted or offset, then the anticline is asymmetrical. An anticline that is cylindrical has a well-defined axial surface, whereas non-cylindrical anticlines are too complex to have a single axial plane.


An overturned anticline is an asymmetrical anticline with a limb that has been tilted beyond perpendicular, so that the beds in that limb have basically flipped over and may dip in the same direction on both sides of the axial plane.[3] If the angle between the limbs is large (70–120 degrees), then the fold is an "open" fold, but if the angle between the limbs is small (30 degrees or less), then the fold is a "tight" fold.[4] If an anticline plunges (i.e., the anticline crest is inclined to the Earth's surface), it will form Vs on a geologic map view that point in the direction of plunge. A plunging anticline has a hinge that is not parallel to the earth's surface. All anticlines and synclines have some degree of plunge. Periclinal folds are a type of anticlines that have a well-defined, but curved hinge line and are doubly plunging and thus elongate domes.[5]




Model of anticline. Oldest beds are in the center and youngest on the outside. The axial plane intersects the center angle of bend. The hinge line follows the line of greatest bend, where the axial plane intersects the outside of the fold.


Folds in which the limbs dip toward the hinge and display a more U-like shape are called synclines. They usually flank the sides of anticlines and display opposite characteristics. A syncline's oldest rock strata are in its outer limbs; the rocks become progressively younger toward its hinge. A monocline is a bend in the strata resulting in a local steepening in only one direction of dip.[2] Monoclines have the shape of a carpet draped over a stairstep.[4]


An anticline that has been more deeply eroded in the center is called a breached or scalped anticline. Breached anticlines can become incised by stream erosion, forming an anticlinal valley.


A structure that plunges in all directions to form a circular or elongate structure is a dome. Domes may be created via diapirism from underlying magmatic intrusions or upwardly mobile, mechanically ductile material such as rock salt (salt dome) and shale (shale diapir) that cause deformations and uplift in the surface rock. The Richat Structure of the Sahara is considered a dome that has been laid bare by erosion.


An anticline which plunges at both ends is termed a doubly plunging anticline, and may be formed from multiple deformations, or superposition of two sets of folds. It may also be related to the geometry of the underlying detachment fault and the varying amount of displacement along the surface of that detachment fault.


An anticlinorium is a large anticline in which a series of minor anticlinal folds are superimposed. Examples include the Late Jurassic to Early Cretaceous Purcell Anticlinorium in British Columbia[1] and the Blue Ridge anticlinorium of northern Virginia and Maryland in the Appalachians,[6] or the Nittany Valley in central Pennsylvania.



Formation processes




Anticline near Ehden, Lebanon


Anticlines are usually developed above thrust faults, so any small compression and motion within the inner crust can have large effects on the upper rock stratum. Stresses developed during mountain building or during other tectonic processes can similarly warp or bend bedding and foliation (or other planar features). The more the underlying fault is tectonically uplifted, the more the strata will be deformed and must adapt to new shapes. The shape formed will also be very dependent on the properties and cohesion of the different types of rock within each layer.


During the formation of flexural-slip folds, the different rock layers form parallel-slip folds to accommodate for buckling. A good way to visualize how the multiple layers are manipulated, is to bend a deck of cards and to imagine each card as a layer of rock stratum.[7] The amount of slip on each side of the anticline increases from the hinge to the inflection point.[2]


Passive-flow folds form when the rock is so soft that it behaves like weak plastic and slowly flows. In this process different parts of the rock body move at different rates causing shear stress to gradually shift from layer to layer. There is no mechanical contrast between layers in this type of fold. Passive-flow folds are extremely dependent on the rock composition of the stratum and can typically occur in areas with high temperatures.[4]



Economic significance


Anticlines, structural domes, fault zones and stratigraphic traps are very favorable locations for oil and natural gas drilling. About 80 percent of the world’s petroleum has been found in anticlinal traps.[8] The low density of petroleum causes oil to buoyantly migrate out of its source rock and upward toward the surface until it is trapped and stored in reservoir rock such as sandstone or porous limestone. The oil becomes trapped along with water and natural gas by a caprock that is made up of impermeable barrier such as an impermeable stratum or fault zone.[9] Examples of low-permeability seals that contain the hydrocarbons, oil and gas, in the ground include shale, limestone, sandstone, and even salt domes. The actual type of stratum does not matter as long as it has low permeability.


Water, minerals and specific rock strata such as limestone found inside anticlines are also extracted and commercialized. Lastly, ancient fossils are often found in anticlines and are used for paleontological research or harvested into products to be sold.



Notable examples



Asia


Ghawar Anticline, Saudi Arabia, the structural trap for the largest conventional oil field in the world.



Australia


  • Hill End Anticline, New South Wales, which is associated with deposits of gold.
  • Castlemaine Anticlinal Fold, Victoria, which is celebrated with a plaque that says, "This fine exhibit was disclosed when Lyttleton Street East was constructed in 1874. Saddle reefs occur in similar folds of the sandstones and slates on lower geological horizons."


Europe





Harpea's Cave in southern France


The Weald–Artois Anticline is a major anticline which outcrops in southeast England and northern France. It was formed from the late Oligocene to middle Miocene, during the Alpine orogeny.



North America


Anticlines can have a major effect on the local geomorphology and economy of the regions in which they occur. One example of this is the El Dorado anticline in Kansas. The anticline was first tapped into for its petroleum in 1918. Soon after the site became a very prosperous area for entrepreneurs following World War I and the rapid popularization of motor vehicles. By 1995 the El Dorado oil fields had produced 300 million barrels of oil.[10] The central Kansas uplift is an antiform composed of several small anticlines that have collectively produced more than 2.5 million barrels of oil.[11]


Another notable anticline is the Tierra Amarilla anticline in San Ysidro, New Mexico.[12] This is a popular hiking and biking site because of the great biodiversity, geologic beauty and paleontological resources. This plunging anticline is made up of Petrified Forest mudstones and sandstone and its caprock is made of Pleistocene and Holocene travertine. The anticline contains springs that deposit carbon dioxide travertine that help to contribute to the rich diversity of microorganisms.[13] This area also contains remains of fossils and ancient plants from the Jurassic period that are sometimes exposed through geological erosion.


The Ventura Anticline is a geologic structure that is part of the Ventura oil fields, the seventh largest oil field in California that was discovered in the 1860s. The anticline runs east to west for 16 miles, dipping steeply 30–60 degrees at both ends. Ventura County has a high rate of compression and seismic activity due to the converging San Andreas Fault. As a result, the Ventura anticline rises at a rate of 5 mm/year with the adjacent Ventura Basin converging at a rate of about 7–10 mm/year.[14] The anticline is composed of a series of sandstone rock beds and an impermeable rock cap under which vast reserves of oil and gas are trapped. Eight different oil bearing zones along the anticline vary greatly from 3,500 to 12,000 feet. The oil and gas formed these pools as they migrated upward during the Pliocene Era and became contained beneath the caprock. This oil field is still active and has a cumulative production of one billion barrels of oil making it one of the most vital historical and economic features of Ventura County.[15]



Gallery



See also




  • Homocline

  • River anticlines


References




  1. ^ abc Dictionary of Geological Terms (3rd ed.). Garden City, New York: Anchor Press/Doubleday. April 11, 1984. ISBN 978-0-385-18101-3..mw-parser-output cite.citationfont-style:inherit.mw-parser-output .citation qquotes:"""""""'""'".mw-parser-output .citation .cs1-lock-free abackground:url("//upload.wikimedia.org/wikipedia/commons/thumb/6/65/Lock-green.svg/9px-Lock-green.svg.png")no-repeat;background-position:right .1em center.mw-parser-output .citation .cs1-lock-limited a,.mw-parser-output .citation .cs1-lock-registration abackground:url("//upload.wikimedia.org/wikipedia/commons/thumb/d/d6/Lock-gray-alt-2.svg/9px-Lock-gray-alt-2.svg.png")no-repeat;background-position:right .1em center.mw-parser-output .citation .cs1-lock-subscription abackground:url("//upload.wikimedia.org/wikipedia/commons/thumb/a/aa/Lock-red-alt-2.svg/9px-Lock-red-alt-2.svg.png")no-repeat;background-position:right .1em center.mw-parser-output .cs1-subscription,.mw-parser-output .cs1-registrationcolor:#555.mw-parser-output .cs1-subscription span,.mw-parser-output .cs1-registration spanborder-bottom:1px dotted;cursor:help.mw-parser-output .cs1-ws-icon abackground:url("//upload.wikimedia.org/wikipedia/commons/thumb/4/4c/Wikisource-logo.svg/12px-Wikisource-logo.svg.png")no-repeat;background-position:right .1em center.mw-parser-output code.cs1-codecolor:inherit;background:inherit;border:inherit;padding:inherit.mw-parser-output .cs1-hidden-errordisplay:none;font-size:100%.mw-parser-output .cs1-visible-errorfont-size:100%.mw-parser-output .cs1-maintdisplay:none;color:#33aa33;margin-left:0.3em.mw-parser-output .cs1-subscription,.mw-parser-output .cs1-registration,.mw-parser-output .cs1-formatfont-size:95%.mw-parser-output .cs1-kern-left,.mw-parser-output .cs1-kern-wl-leftpadding-left:0.2em.mw-parser-output .cs1-kern-right,.mw-parser-output .cs1-kern-wl-rightpadding-right:0.2em


  2. ^ abc Hefferan, Kevin P. "Folds". Geology 320: Structural Geology. University of Wisconsin–Stevens Point. Retrieved December 8, 2015.


  3. ^ Mantei, Erwin J. "Geologic Structures—Crustal Deformations". Physical Geology (GLG110). Missouri State University. Retrieved December 17, 2015.


  4. ^ abc Marshak, Stephen (2012). Earth: Portrait of a Planet (4th ed.). Norton. ISBN 978-0393935189. Retrieved January 22, 2016.


  5. ^ Roberts, Albert F. (1947). Geological Structures and Maps: A Practical Course in the Interpretation of Geological Maps for Civil and Mining Engineers. London: I. Pitman. p. 33.


  6. ^ Monroe, James S.; Wicander, Reed (February 8, 2005). The Changing Earth: Exploring Geology and Evolution (4th ed.). Brooks Cole. ISBN 978-0-495-01020-3.
    [page needed]



  7. ^ Earle, Steven (2015). "Folding". Physical Geology. Retrieved December 15, 2015.


  8. ^ Riva, Joseph P. "Accumulation in reservoir beds". Encyclopædia Britannica. Retrieved December 10, 2015.


  9. ^ Society of Petroleum Engineers Student Chapter (November 9, 2014). "Petroleum 101 – How is Petroleum Formed?". University of Waterloo. Retrieved December 10, 2015.


  10. ^ Skelton, L.H. (1997). "The Discovery and Development of the El Dorado (Kansas) Oil Field". Northeastern Geology and Environmental Sciences. 19 (1–2): 48–53. Retrieved December 15, 2015.


  11. ^ Baars, D.L.; Watney, W. Lynn; Steeples, Don W.; Brostuen, Erling A. (April 2001). "Petroleum: a primer for Kansas – Structure". Kansas Geological Survey, Education. p. 5. Retrieved December 9, 2015.


  12. ^ Hart, Dirk Van (February 2003). "Gallery of Geology – Tierra Amarilla Anticline" (PDF). New Mexico Geology. 25 (1): 15. Retrieved December 15, 2015.


  13. ^ Cron, Brandi; Crossey, Laura J.; Karlstrom, Karl E.; Northup, Diana E.; Takacs-Vesbach, Cristina (2009). "Microbial Diversity, Geochemistry and Diel Fluctuations in Travertine Mounds at Tierra Amarilla Anticline, New Mexico". Abstracts with Programs. Geological Society of America. 41 (7): 322. Retrieved December 8, 2015.


  14. ^ O'Tousa, Jim (August 7, 2014). "Overview of the Geology of Ventura County including Seismicity, Oil and Gas Plays and Groundwater Resources" (PDF). Oil and Gas Program Informational Workshop. Ventura County Planning Commission. Archived from the original (PDF) on February 2, 2016.


  15. ^ Jackson, Glenda (July 2013). "Oil and Ventura" (PDF). Ventura City Hall.




Bibliography



  • Davis, George H.; Reynolds, Stephen J. (January 19, 1996). Structural Geology of Rocks and Regions (2nd ed.). New York: John Wiley & Sons. ISBN 978-0-471-52621-6.


  • Monroe, James S.; Wicander, Reed (February 8, 2005). The Changing Earth: Exploring Geology and Evolution (4th ed.). Brooks Cole. ISBN 978-0-495-01020-3.


  • Weijermars, Ruud (1997). Structural Geology and Map Interpretation. Lectures in geoscience. Amsterdam: Alboran Science Publishing. ISBN 90-5674-001-6 – via Delft University of Technology.Entire book is freely available in PDF format.


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