basin and range topography
{{Short description|Alternating landscape of parallel mountain ranges and valleys}}
{{Distinguish|Basin and Range Province}}
File:Wheeler Peak and Great Basin National Park.jpg
Basin and range topography is characterized by alternating parallel mountain ranges and valleys. It is a result of crustal extension due to mantle upwelling, gravitational collapse, crustal thickening, or relaxation of confining stresses.{{Cite web|url=http://www.geol.ucsb.edu/faculty/gans/abstracts/gans1993.html|title=Extension of the Basin and Range Province: Late orogenic collapse or something else?|last=Gans, P. B., & Miller, E. L.|access-date=May 11, 2017}}{{Cite journal|last=Liu, M., Shenm, Y.|date=1998|title=Crustal collapse, mantle upwelling, and cenozoic extension in the north american cordillera|journal=Tectonics|volume=17 |issue=2|pages=311–321|doi=10.1029/98tc00313|bibcode=1998Tecto..17..311L|doi-access=free}} The extension results in the thinning and deformation of the upper crust, causing it to fracture and create a series of long parallel normal faults. This results in block faulting, where the blocks of rock between the normal faults either subside, uplift, or tilt. The movement of these blocks results in the alternating valleys and mountains. As the crust thins, it also allows heat from the mantle to more easily melt rock and form magma, resulting in increased volcanic activity.{{Cite web|last=Scott|first=Nicolle|date=April 17, 2012|title=The Basin and Range Province of the United States|url=http://academic.emporia.edu/aberjame/student/scott2/basin_range.html|url-status=dead|archive-url=https://web.archive.org/web/20190912201646/http://academic.emporia.edu/aberjame/student/scott2/basin_range.html|archive-date=September 12, 2019|website=Emporia State University}}
Types of faulting
= Symmetrical faulting: horst and graben =
{{Main|Horst and graben}}
With crustal extension, a series of normal faults which occur in groups, form in close proximity and dipping in opposite directions.{{Cite web|url=http://www.geosci.usyd.edu.au/users/prey/ACSGT/EReports/eR.2003/GroupD/Report2/web%20pages/Types_of_Structures.html|title=Structures of Sedimentary Basins|last=Hutson, P., Middleton, J., Miller, D., & Wallenstein, A.}} As the crust extends it fractures in series of fault planes, some blocks sink down due to gravity, creating long linear valleys or basins also known as grabens, while the blocks remaining up or uplifted produce mountains or ranges, also known as horsts. Fault scarps are exposed on the horst block and expose the footwall of the normal fault. This is a type of block faulting known as grabens and horsts. This basin and range topography is symmetrical having equal slopes on both sides of the valleys and mountain ranges.
= Asymmetric faulting: tilted block faulting =
{{Main| Tilted block faulting}}
Tilted block faulting, also known as half-graben or rotational block faulting, can also occur during extension. Large gently dipping normal faults, also known as detachment faults, act as platforms in which normal faulted blocks tilt or slide along. However, instead of the whole block subsiding only one side, the block may slip along the detachment fault, tilting toward the fault plane, again creating mountains (ranges) and valleys (basins), many tilted slightly in one direction at their tops due to the motion of their bottoms along the main detachment fault. This basin and range topography has one steep side and the other is more gradual.
{{Clear}}
Examples
= Basin and Range Province =
{{Main|Basin and Range Province}}
The Basin and Range Province is the most well known example of basin and range topography. Clarence Dutton compared the many narrow parallel mountain ranges that distinguish the unique topography of the Basin and Range to an "army of caterpillars crawling northward."{{Cite journal|last=Dutton|first=Clarence|date=1885|title=Mount Taylor and the Zuni Plateau|url=https://ngmdb.usgs.gov/Prodesc/proddesc_92540.htm|journal=Sixth Annual Report of the United States Geological Survey to the Secretary of the Interior, 1884-1885|publisher=U.S. Geological Survey|volume=|pages=113–198|doi=10.3133/ar6|doi-access=free}}
The physiography of the province is the result of tectonic extension that began around 17 million years ago in the early Miocene epoch. Opinions vary regarding the total extension of the region; however, the median estimate is about 100% total lateral extension.{{cite web|url=http://geomaps.wr.usgs.gov/parks/province/basinrange.html|title=Geologic Provinces of the United States: Basin and Range Province|archive-url=https://web.archive.org/web/20090125163038/http://geomaps.wr.usgs.gov/parks/province/basinrange.html |archive-date=2009-01-25|publisher=USGS}} The tectonic mechanisms responsible for lithospheric extension in the Basin and Range province are controversial, and several competing hypotheses attempt to explain them.{{cite book|last=Stanley|first=SM|year=2005|title=Earth system history|location=New York|publisher=Freeman}}{{citation|last=Stern|first=Robert J|type=Class Notes|title=Rifts|work=Physics and Chemistry of the Solid Earth|publisher=University of Texas at Dallas|location=Dallas, Texas|date=2010-09-01}}{{cite journal|first1=Makoto|last1=Yamano|first2=Masataka|last2=Kinoshita|first3=Shusaku|last3=Goto|title=High heat flow anomalies on an old oceanic plate observed seaward of the Japan Trench|journal=International Journal of Earth Sciences|year=2008|volume=97|issue=2|pages=345–52|doi=10.1007/s00531-007-0280-1|bibcode=2008IJEaS..97..345Y|s2cid=129417881}}
= Aegean Sea Plate =
{{Main|Aegean Sea Plate}}
The Aegean Sea Plate consists of thinned continental crust. The northern part of the plate is currently a region of crustal extension caused by slab rollback on the Hellenic Subduction Zone to the south, causing extensive normal faulting and the formation of horsts and grabens on the seafloor. Many of the islands are the result of peaks reaching above sea level.{{Cite book|last1=Higgins|first1=MD|url=https://www.researchgate.net/publication/257233658|title=A Geological Companion to Greece and the Aegean|last2=Higgins|first2=R|publisher=Duckworth Publishers, London|year=1996|pages=16–25}}{{Cite web|title=Basins and ranges|url=http://www.britannica.com/EBchecked/topic/585476/tectonic-basins-and-rift-valleys/49680/Basins-and-ranges|url-status=live|website=Encyclopædia Britannica|archive-url=https://web.archive.org/web/20110312080846/http://www.britannica.com:80/EBchecked/topic/585476/tectonic-basins-and-rift-valleys/49680/Basins-and-ranges |archive-date=2011-03-12 }}
Mapping extension
One of the most studied basin and range topographies is the Basin and Range Province in the western United States, located between the Sierra Nevada and the Rocky Mountains. The extension of the province was believed to have begun in the late Cenozoic Era, roughly 20 Ma.{{Cite journal|last=Thompson, G. A., and Burke, D. B.|date=1974|title=Regional geophysics of the Basin and Range Province|journal=Annual Review of Earth and Planetary Sciences|volume=2|pages=213–238|doi=10.1146/annurev.ea.02.050174.001241|bibcode=1974AREPS...2..213T }} Between 1992 and 1998 scientists conducted GPS surveys to map the deformation of the Basin and Range province.{{Cite journal|last=Thatcher, W., Foulger, G., Julian, B., Svarc, J., Quilty, E., & Bawden, G.|date=1999|title=Present-Day Deformation Across the Basin and Range Province, Western United States|url=https://zenodo.org/record/1231153|journal=Science|volume=283|issue=5408|pages=1714–1718|bibcode=1999Sci...283.1714T|doi=10.1126/science.283.5408.1714|pmid=10073932 }} In the study, Thatcher et al. discovered that most deformation was happening in the west, adjacent to the Sierra Nevada block, while less deformation was happening in the east. This coincides with the northwestward movement of the Sierra Nevada microplate.{{Cite journal|last=Unruh, J., Humphrey, J., & Barron, A.|date=2003|title=Transtensional model for the Sierra Nevada frontal fault system, eastern California|journal=Geology|volume=31|issue=4|pages=327|bibcode=2003Geo....31..327U|doi=10.1130/0091-7613(2003)031<0327:tmftsn>2.0.co;2}}
Though the Aegean Sea Plate is more difficult to study because it is underwater, efforts have been made to conduct GPS surveys of the seafloor and surrounding area. Some studies show regions of extension within the plate, while others suggest a four-microplate model to represent the motion.{{Cite journal|last1=Nyst|first1=Marleen|last2=Thatcher|first2=Wayne|date=2004-11-24|title=New constraints on the active tectonic deformation of the Aegean: GPS CONSTRAINTS ON AEGEAN DEFORMATION|url=http://doi.wiley.com/10.1029/2003JB002830|journal=Journal of Geophysical Research: Solid Earth|language=en|volume=109|issue=B11|doi=10.1029/2003JB002830}} The plate's deformation is thought to be a result of crustal collapse (beginning {{circa}} 14 Ma) combined with slab rollback on the Hellenic Subduction Zone.{{Cite journal|last1=Searle|first1=Michael P.|last2=Lamont|first2=Thomas N.|date=2020-08-07|title=Compressional origin of the Aegean Orogeny, Greece|journal=Geoscience Frontiers|volume=13 |issue=2 |page=101049 |language=en|doi=10.1016/j.gsf.2020.07.008|s2cid=225356710 |issn=1674-9871|doi-access=free}}{{Cite journal|last1=Sodoudi|first1=F.|last2=Kind|first2=R.|last3=Hatzfeld|first3=D.|last4=Priestley|first4=K.|last5=Hanka|first5=W.|last6=Wylegalla|first6=K.|last7=Stavrakakis|first7=G.|last8=Vafidis|first8=A.|last9=Harjes|first9=H.-P.|last10=Bohnhoff|first10=M.|date=2006|title=Lithospheric structure of the Aegean obtained from P and S receiver functions|journal=Journal of Geophysical Research: Solid Earth|volume=111|issue=B12|pages=|doi=10.1029/2005jb003932|bibcode=2006JGRB..11112307S |issn=|doi-access=free|hdl=11858/00-1735-0000-0001-3290-3|hdl-access=free}}
See also
References
{{Reflist}}
External links
- [https://web.archive.org/web/20080521002117/http://www.data.scec.org/glossary.html Southern California Earthquake Data Center Glossary]