Nevadaplano
The Nevadaplano was a high plateau that is proposed to have covered parts of southwestern North America during the late Mesozoic and early Cenozoic, located in the present-day US states of Idaho, Nevada, Utah and possibly others. It most likely formed during the Cretaceous as a consequence of subduction dynamics and may have reached elevations of 3 kilometres (9,800 ft) and more, although its elevation is controversial. It was flanked on the west by the Sierra Nevada, which was traversed by various valleys that came down from the Nevadaplano. Closed basins and numerous volcanic calderas covered the relatively flat Nevadaplano; large volcanic eruptions distributed ignimbrites over the plateau and down the valleys draining it.
During the Miocene, changes in the tectonic regime may have caused a collapse and dismemberment of the Nevadaplano. Tectonic extension gave rise to the Basin and Range province and separated the Sierra Nevada-Great Valley block from the Nevadaplano, forming today's landscape.
Research history
[edit]The existence of the Nevadaplano was proposed in 2004 by DeCelles[1][2] and named after the Altiplano high plateau of South America.[3] It is also known as the "Great Basin Altiplano".[4] Unlike the present-day Andean Altiplano and Tibetan plateau, the Nevadaplano was dismembered during the Cenozoic and thus its structure and evolution are poorly understood.[5]
Geologic history
[edit]The Nevadaplano probably formed as part of either the Sevier[6] or the Laramide Orogeny[7] during the Mesozoic and persisted into the Paleogene.[1] Its growth began either in the Cretaceous or the Jurassic, when significant tectonic shortening took place[8] behind the Sevier orogen. Similar to the present-day Altiplano in South America, the combination of an arid climate, tectonic contraction, weak erosion[1] and the accumulation of volcanic rocks both in and below the crust helped raise the Nevadaplano[9] during the Cretaceous, when flat subduction was taking place.[10] Later, its southern part was probably overprinted by the Laramide Orogeny[6] when volcanism shifted far to the east.[11] The exact geologic evolution and character of the Nevadaplano is controversial, however,[12] as is the notion that it was a geologically stable environment.[13]
The Nevadaplano underwent extensional tectonics during the Cenozoic, possibly in a multi-step process. An early stage may have occurred in the Eocene-Oligocene, toward the end of subduction, when the subducting slab steepened again and slab rollback decreased the tectonic forces. At that time, volcanic activity swept southwestward,[10] away from the volcanoes of central Nevada to the Sierra.[14] This may have been accompanied by uplift[15][16] that would have continued when the Yellowstone hotspot developed in the Miocene.[17] The plateau overrode the heat source of the East Pacific Rise about 28 million years ago.
By far the most significant stage of extension was the later[18] episode of east–west extension and northwestward shearing,[1] which was underway by 16-17 million years ago[19] and continues to a lesser extent today. That extension probably caused the high plateau to lose elevation. The heat flow from the Yellowstone hotspot is one mechanism that has could have caused the collapse process.[17] Also during the Miocene, the Sierra Nevada-Great Valley block separated from the Nevadaplano and was tilted to the west along the Sierra Escarpment,[20] beheading a number of westward-going drainages in the process.[19] Former drainages of the Nevadaplano were buried by volcanic rocks and disrupted by tectonic processes.[21] Farther east, the dismemberment of the drainages may have created suitable environments for the evolution of sucker fish.[22]
Miocene extension also created the well-known Basin and Range extension, probably triggered by changes in the plate boundary between the Pacific Plate and the North American Plate. Presently, relic surfaces around the Middle Fork Feather River valley[23] and the high elevations of the northern Basin and Range may be considered remnants of the Nevadaplano.[17]
The Nevadaplano during its existence
[edit]The Nevadaplano was located in present-day Nevada and Utah, at the location of the present-day Great Basin,[24] and may have extended from what is present-day central Idaho in the north either to Sonora[25] or southern Nevada in the south.[26] It was a high plateau consisting of a peneplain[1] and reached a width of 400–500 kilometres (250–310 mi).[27] Isotope analysis indicates that the Nevadaplano stood at high elevations,[1] probably higher than[28] or comparable to the then-Sierra Nevada. The elevation of the Nevadaplano exceeded 3 kilometres (1.9 mi),[18] but the exact value is controversial,[12] as is whether it was flat or featured rugged topography.[29] There is evidence of basins at its western margin,[30] although the relief of the Nevadaplano is debated and was probably less than that of the Altiplano.[31]
The Nevadaplano probably drained to internal basins such as the Elko[32] and Uinta Basins,[33] the Western Interior Seaway[34] and westward to the Pacific Ocean.[6] A drainage divide extended from the Mogollon Highlands in the south through the Kingman Uplift into the Nevadaplano.[34] There is some uncertainty in the drainage directions across the Nevadaplano, with some evidence interpreted as indicating that drainage divides shifted over time[25] and that the divide between Nevada and Idaho was offset along a Neoproterozoic lineament.[35] Among the reconstructed drainages are the Tyee and Princeton Rivers from what is present-day north-central Idaho to present-day Oregon and northern California, the Idaho River also from present-day north-central Idaho to the Green River basin and the California River from present-day southernmost California to the Uinta Basin.[36] The northernmost among these rivers may have formed the northern boundary of the Nevadaplano.[37]
Some normal faulting took place within the Nevadaplano, along with the exposure of core complexes, and generated isolated basins.[38] This may have created regional basins in the late Cretaceous similar to those that lie in the present-day Altiplano-Puna region, and which include the Sheep Pass Formation basin[39] and the long-lived Elko Basin.[40] Lake sediments and volcanic rocks accumulated in these basins. The formation of these basins may have been an early stage of the collapse of the Nevadaplano.[41]
Geographical and geological boundaries
[edit]West of the Nevadaplano stood the Sierra Nevada, which was volcanically active[1] until 80 million years ago[42] and featured exposed batholiths from former volcanism. Its exact elevation at the time is unclear, with alternate models proposing either that it had already reached a height similar to today's Sierra Nevada or that it rose to present-day height in the Miocene and Pliocene.[12] Alternatively, the Luning-Fencemaker fold-and-thrust belt may have formed the western boundary.[43]
It probably did not constitute a drainage divide;[12] various east–west trending[44] valleys cut across the Sierra Nevada at that time. Presently filled with volcanic and sedimentary rocks,[20] these valleys were 5–8 kilometres (3.1–5.0 mi) wide, 0.5–1.2 kilometres (0.31–0.75 mi) deep with flat and deeply weathered bottoms.[45] Among these valleys are the Nine Hill and Soda Springs valleys in the Lake Tahoe region[46] and the Stanislaus, Mokelumne and Cataract paleochannels in the Sonora Pass region.[47] There is more evidence for paleovalleys in the northern Sierra Nevada than in the southern,[48] which may either indicate that evidence of cross-Sierra drainage was removed in its southern sector or that the southern Sierra was higher than the central and northern Sierra at the time of the Nevadaplano.[49] Some of these rivers may have been large enough to allow sharks to reach Nevada.[50] The rivers flowing through these valleys deposited the placer gold deposits of California,[3] as part of intense westward sediment transport.[51] On the eastern side, the proto-Platte and proto-Arkansas Rivers drained the Nevadaplano.[52]
Remnants of the Laramide uplands, the Chusca erg[53] or the Sevier fold-and-thrust belt were located east of the Nevadaplano.[54] The boundary was located at a region corresponding to the present-day Wasatch, Santaquin and Canyon Ranges.[55] A relatively short distance may have separated it there from the Western Interior Seaway.[56] The region of what today is northern Nevada during the Oligocene may have been a gently tilted or closed plateau.[57] To the south, the California River may have separated the Nevadaplano from an analogous high plateau to the south, called "Mexicoplano"[58] or "Arizonaplano".[59] The Colorado Plateau was either to the east of the Nevadaplano[9] or else formed an integral part of the plateau.[18] The San Juan Mountains region may have formed its own upland, the "Colorado-plano".[60]
Geology
[edit]During the Miocene, volcanic activity covered the Nevadaplano with lahars, lava flows and volcanic sediments.[1] In central Nevada and western Utah, at least 71[61] calderas located at high elevation erupted ignimbrites which propagated for over 200 kilometres (120 mi) westward and across former valleys in the Sierra Nevada,[20] filling them in during the process.[61] In particular, the 28.9 million year old[24] Campbell Creek tuff covered an area of 55,000 square kilometres (21,000 sq mi) and propagated far east and west of its source area.[62]
The underlying crust had a sialic composition and reached thicknesses of 45–65 kilometres (28–40 mi).[1] It consisted of metamorphic rocks[1] that are now exposed as metamorphic core complexes such as in the Pequop Mountains of Nevada,[63] as well as plutonic rocks including batholiths.[64]
Ecosystems and climate
[edit]Based on the fossils found in the Sheep Pass Formation, the Nevadaplano likely had a cold high-elevation climate.[65] Located in the rain shadow of the Sierra Nevada, it was dry,[1] and therefore experienced only weak erosion.[18] The rain shadow extended east of the Nevadaplano.[66] However, precipitation was enough to cut large valleys into the Sierra Nevada, perhaps aided by the then-warm climate.[45] Pulses of erosion may have occurred during Paleogene climate disturbances, such as the Paleocene–Eocene Thermal Maximum.[67] Vegetation with temperate climate affinities like giant sequoias may have migrated from or through the Nevadaplano to California[68][69] when the climate cooled during the Oligocene, founding the temperate forest communities of California.[70]
Evidence suggests that lakes and alluvial fans existed on the Nevadaplano,[30] the Sheep Pass Formation constitutes the remnants of such landforms.[39] It is not clear however if the Sheep Pass lake system was at high elevation.[71] Fossils of anurans, birds, bivalves, crustaceans, frogs, lizards, mammals, molluscs, ostracods and snakes have been found there,[72] as well as evidence of algae, charophytes, plants[73] and microbial mats. There are also traces of physical events such as debris flows, periodic desiccation and storms.[74][75] Lakes formed during the disassembly of the Nevadaplano as well, including these where the Truckee Formation diatomites were emplaced in.[76]
References
[edit]- ^ a b c d e f g h i j k Ernst 2009, p. 583.
- ^ DeCelles, P. G. (1 February 2004). "Late Jurassic to Eocene evolution of the Cordilleran thrust belt and foreland basin system, western U.S.A." American Journal of Science. 304 (2): 147. Bibcode:2004AmJS..304..105D. doi:10.2475/ajs.304.2.105. ISSN 0002-9599.
- ^ a b Blakey & Ranney 2018, p. 136.
- ^ Best, Myron G.; Gromme, Sherman.; Deino, Alan L.; Christiansen, Eric H.; Hart, Garret L.; Tingey, David G. (1 December 2013). "The 36–18 Ma Central Nevada ignimbrite field and calderas, Great Basin, USA: Multicyclic super-eruptions". Geosphere. 9 (6): 1563. Bibcode:2013Geosp...9.1562B. doi:10.1130/GES00945.1. ISSN 1553-040X.
- ^ Zuza et al. 2020, p. 1.
- ^ a b c Henry et al. 2012, p. 23.
- ^ Wakabayashi, John (1 April 2013). "Paleochannels, stream incision, erosion, topographic evolution, and alternative explanations of paleoaltimetry, Sierra Nevada, California". Geosphere. 9 (2): 209. Bibcode:2013Geosp...9..191W. doi:10.1130/GES00814.1. ISSN 1553-040X.
- ^ Zuza et al. 2020, p. 15.
- ^ a b Erdman et al. 2016, p. 54.
- ^ a b Busby & Putirka 2009, p. 676.
- ^ Erdman et al. 2016, p. 48.
- ^ a b c d Henry et al. 2012, p. 2.
- ^ Lund Snee & Miller 2022, p. 352.
- ^ Busby et al. 2016, p. 140.
- ^ Lund Snee & Miller 2022, p. 335.
- ^ Camp, Pierce & Morgan 2015, p. 204.
- ^ a b c Camp, Pierce & Morgan 2015, p. 218.
- ^ a b c d Ernst 2010, p. 70.
- ^ a b Ernst 2009, p. 586.
- ^ a b c Ernst 2009, p. 584.
- ^ Busby & Putirka 2009, p. 695.
- ^ Smith, Gerald R.; Stewart, Joseph D.; Carpenter, Nathan E. (30 May 2013). Fossil And Recent Mountain Suckers, Pantosteus, And Significance Of Introgression In Catostomin Fishes Of Western United States (Report). p. 34. hdl:2027.42/122717.
- ^ Hurst, Martin D.; Mudd, Simon M.; Walcott, Rachel; Attal, Mikael; Yoo, Kyungsoo (June 2012). "Using hilltop curvature to derive the spatial distribution of erosion rates: HILLTOP CURVATURE PREDICTS EROSION RATES". Journal of Geophysical Research: Earth Surface. 117 (F2): 5. doi:10.1029/2011JF002057. hdl:20.500.11820/62605844-86fc-46f3-a614-1b1bdccebe12. S2CID 54824033.
- ^ a b Henry et al. 2012, p. 1.
- ^ a b Henry et al. 2012, p. 21.
- ^ Busby, Cathy J. (1 October 2013). "Birth of a plate boundary at ca. 12 Ma in the Ancestral Cascades arc, Walker Lane belt of California and Nevada". Geosphere. 9 (5): 1153. Bibcode:2013Geosp...9.1147B. doi:10.1130/GES00928.1. ISSN 1553-040X.
- ^ Dickinson, William R. (1 October 2013). "Phanerozoic palinspastic reconstructions of Great Basin geotectonics (Nevada-Utah, USA)". Geosphere. 9 (5): 1388. Bibcode:2013Geosp...9.1384D. doi:10.1130/GES00888.1. ISSN 1553-040X.
- ^ Camp, Pierce & Morgan 2015, p. 205.
- ^ Lund Snee & Miller 2022, p. 336.
- ^ a b Ernst 2010, p. 72.
- ^ Long 2012, p. 896.
- ^ Smith et al. 2017, p. 167.
- ^ Karlstrom et al. 2020, p. 1449.
- ^ a b Karlstrom et al. 2020, p. 1448.
- ^ Henry et al. 2012, p. 22.
- ^ Dumitru, Trevor A.; Ernst, W.G.; Hourigan, Jeremy K.; McLaughlin, Robert J. (11 June 2015). "Detrital zircon U–Pb reconnaissance of the Franciscan subduction complex in northwestern California". International Geology Review. 57 (5–8): 778. Bibcode:2015IGRv...57..767D. doi:10.1080/00206814.2015.1008060. S2CID 128542566.
- ^ Dumitru, T. A. (1 December 2016). "Six Cordilleran Paleorivers that Connected Deforming Highlands in Idaho to Depocenters in California, Oregon, Washington, and Wyoming". AGU Fall Meeting Abstracts. 53. Bibcode:2016AGUFM.T53D..07D.
- ^ Camp, Pierce & Morgan 2015, p. 206.
- ^ a b Bonde et al. 2020, p. 3.
- ^ Horton, Travis W.; Oze, Christopher (June 2012). "Are two elements better than one? Dual isotope-ratio detrending of evaporative effects on lake carbonate paleoelevation proxies: 13 C-EXCESS DETRENDING OF EVAPORATION". Geochemistry, Geophysics, Geosystems. 13 (6): 11. doi:10.1029/2012GC004132.
- ^ Greene, David C. (1 February 2014). "The Confusion Range, west-central Utah: Fold-thrust deformation and a western Utah thrust belt in the Sevier hinterland". Geosphere. 10 (1): 149. Bibcode:2014Geosp..10..148G. doi:10.1130/GES00972.1. ISSN 1553-040X.
- ^ Smith et al. 2017, p. 157.
- ^ DeCelles & Coogan 2006, p. 858.
- ^ Busby & Putirka 2009, p. 682.
- ^ a b Henry et al. 2012, p. 16.
- ^ Henry & Faulds 2010, p. 344.
- ^ Busby et al. 2016, p. 172.
- ^ Henry et al. 2012, p. 18.
- ^ Henry et al. 2012, p. 20.
- ^ Bonde, Joshua W. (2015). Fauna of the Newark canyon formation (Lower Cretaceous), East-Central Nevada. 2015 Geological Society of Nevada Symposium Volume. Reno, Nevada. p. 148 – via Academia.edu.
- ^ Blakey & Ranney 2018, p. 146.
- ^ Pecha, Mark E.; Blum, Michael D.; Gehrels, George E.; Sundell, Kurt E.; Karlstrom, Karl E.; Gonzales, David A.; Malone, David H.; Mahoney, J. Brian (3 May 2022). "Linking the Gulf of Mexico and Coast Mountains batholith during late Paleocene time: Insights from Hf isotopes in detrital zircons". Tectonic Evolution of the Sevier-Laramide Hinterland, Thrust Belt, and Foreland, and Postorogenic Slab Rollback (180–20 Ma). p. 270. doi:10.1130/2021.2555(10). ISBN 9780813725550.
- ^ Dickinson, William R. (1 February 2013). "Rejection of the lake spillover model for initial incision of the Grand Canyon, and discussion of alternatives". Geosphere. 9 (1): 13. Bibcode:2013Geosp...9....1D. doi:10.1130/GES00839.1. ISSN 1553-040X.
- ^ Snell et al. 2014, p. 52.
- ^ Long 2012, p. 894.
- ^ DeCelles & Coogan 2006, pp. 858–859.
- ^ Cassel, E. J.; Henry, C. D.; Graham, S. A.; Chamberlain, C. P.; Grove, M. (1 December 2011). "Oligocene Provenance, Drainage Morphology, and Topography of the Nevadaplano". AGU Fall Meeting Abstracts. 23: T23H–06. Bibcode:2011AGUFM.T23H..06C.
- ^ Dickinson, William R.; Lawton, Timothy F.; Pecha, Mark; Davis, Steven J.; Gehrels, George E.; Young, Richard A. (1 August 2012). "Provenance of the Paleogene Colton Formation (Uinta Basin) and Cretaceous–Paleogene provenance evolution in the Utah foreland: Evidence from U-Pb ages of detrital zircons, paleocurrent trends, and sandstone petrofacies". Geosphere. 8 (4): 876. doi:10.1130/GES00763.1. ISSN 1553-040X.
- ^ Chapman, James B.; Greig, Roy; Haxel, Gordon B. (22 November 2019). "Geochemical evidence for an orogenic plateau in the southern U.S. and northern Mexican Cordillera during the Laramide orogeny". Geology. 48 (2): 167. doi:10.1130/G47117.1. ISSN 0091-7613. S2CID 213833576.
- ^ Lipman, Peter W. (1 September 2021). "Raising the West: Mid-Cenozoic Colorado-plano related to subvolcanic batholith assembly in the Southern Rocky Mountains (USA)?". Geology. 49 (9): 1110. Bibcode:2021Geo....49.1107L. doi:10.1130/G48963.1. S2CID 236223919.
- ^ a b Henry & Faulds 2010, p. 340.
- ^ Henry et al. 2012, p. 15.
- ^ Zuza et al. 2020, p. 17.
- ^ Fayon, A.K.; Tikoff, B.; Kahn, M.; Gaschnig, R.M. (1 April 2017). "Cooling and exhumation of the southern Idaho batholith". Lithosphere. 9 (2): 311. Bibcode:2017Lsphe...9..299F. doi:10.1130/L565.1. ISSN 1941-8264.
- ^ Bonde et al. 2020, p. 18.
- ^ Suarez, Celina A.; González, Luis A.; Ludvigson, Gregory A.; Kirkland, James I.; Cifelli, Richard L.; Kohn, Matthew J. (1 November 2014). "Multi-Taxa Isotopic Investigation of Paleohydrology In the Lower Cretaceous Cedar Mountain Formation, Eastern Utah, U.S.A.: Deciphering Effects Of the Nevadaplano Plateau On Regional ClimateINFLUENCE OF THE NEVADAPLANO PLATEAU ON A CRETACEOUS FORELAND BASIN" (PDF). Journal of Sedimentary Research. 84 (11): 986. doi:10.2110/jsr.2014.76. hdl:1808/19198. ISSN 1527-1404.
- ^ Bidgoli, T.; Walker, J. D.; Stockli, D. F. (1 December 2014). "Two-Phase Development of the Nevadaplano, Western Nevada and Southern California, from Low-Temperature Thermochronology". AGU Fall Meeting Abstracts. 21: EP21B–3534. Bibcode:2014AGUFMEP21B3534B.
- ^ Schaffer, Jeffrey P. (2023). "The Sierra Nevada (California) Is a Relict Tropical Late Cretaceous Range: A Field Guide to the Evidence". Yearbook of the Association of Pacific Coast Geographers. 85 (1): 121. doi:10.1353/pcg.2023.a913573. S2CID 265554409.
- ^ Fritsch, Peter W.; Nowell, Camille F.; Leatherman, Lila S.T.; Gong, Wei; Cruz, Boni C.; Burge, Dylan O.; Delgado-Salinas, Alfonso (September 2018). "Leaf adaptations and species boundaries in North American Cercis : implications for the evolution of dry floras". American Journal of Botany. 105 (9): 1588. doi:10.1002/ajb2.1155. PMID 30207598. S2CID 52191030.
- ^ Rundel, Philip W.; Arroyo, Mary T.K.; Cowling, Richard M.; Keeley, Jon E.; Lamont, Byron B.; Vargas, Pablo (November 2016). "Mediterranean Biomes: Evolution of Their Vegetation, Floras, and Climate". Annual Review of Ecology, Evolution, and Systematics. 47 (1): 387–388. doi:10.1146/annurev-ecolsys-121415-032330. ISSN 1543-592X.
- ^ Snell et al. 2014, p. 61.
- ^ Bonde et al. 2020, pp. 3, 8, 18.
- ^ Bonde et al. 2020, p. 7.
- ^ Bonde, Joshua (2011). "Frog taphonomy in a high elevation lake basin on the Nevadaplano, Late Cretaceous to Eocene, Sheep Pass Formation, east-central Nevada". Journal of Vertebrate Paleontology. 31 (60). SOC VERTEBRATE PALEONTOLOGY: 74. doi:10.1080/02724634.2011.10635174. S2CID 210915628.
- ^ Snell et al. 2014, p. 53.
- ^ Stearley, Ralph F.; Smith, Gerald R. (14 October 2016). FISHES OF THE MIO-PLIOCENE WESTERN SNAKE RIVER PLAIN AND VICINITY (Report). p. 21. hdl:2027.42/134040. ISSN 0076-8405.
Sources
[edit]- Blakey, Ronald C.; Ranney, Wayne D. (2018). Ancient Landscapes of Western North America: A Geologic History with Paleogeographic Maps. Cham: Springer International Publishing. Bibcode:2018alwn.book.....B. doi:10.1007/978-3-319-59636-5. ISBN 978-3-319-59634-1. S2CID 135068665.
- Bonde, Joshua W.; Druschke, Peter A.; Hilton, Richard P.; Henrici, Amy C.; Rowland, Stephen M. (2020). "Preservation of latest Cretaceous (Maastrichtian)-Paleocene frogs (Eorubeta nevadensis) of the Sheep Pass Formation of east-central Nevada and implications for paleogeography of the Nevadaplano". PeerJ. 8: e9455. doi:10.7717/peerj.9455. ISSN 2167-8359. PMC 7341540. PMID 32704447.
- Busby, Cathy J.; Putirka, Keith (July 2009). "Miocene evolution of the western edge of the Nevadaplano in the central and northern Sierra Nevada: palaeocanyons, magmatism, and structure". International Geology Review. 51 (7–8): 670–701. Bibcode:2009IGRv...51..670B. doi:10.1080/00206810902978265. S2CID 44056471.
- Busby, C.J.; Andrews, G.D.M.; Koerner, A.K.; Brown, S.R.; Melosh, B.L.; Hagan, J.C. (1 February 2016). "Progressive derangement of ancient (Mesozoic) east-west Nevadaplano paleochannels into modern (Miocene–Holocene) north-northwest trends in the Walker Lane Belt, central Sierra Nevada". Geosphere. 12 (1): 135–175. Bibcode:2016Geosp..12..135B. doi:10.1130/GES01182.1. ISSN 1553-040X.
- Camp, Victor E.; Pierce, Kenneth L.; Morgan, Lisa A. (1 April 2015). "Yellowstone plume trigger for Basin and Range extension, and coeval emplacement of the Nevada–Columbia Basin magmatic belt". Geosphere. 11 (2): 203–225. Bibcode:2015Geosp..11..203C. doi:10.1130/GES01051.1. ISSN 1553-040X.
- DeCelles, Peter G.; Coogan, James C. (1 July 2006). "Regional structure and kinematic history of the Sevier fold-and-thrust belt, central Utah". GSA Bulletin. 118 (7–8): 841–864. Bibcode:2006GSAB..118..841D. doi:10.1130/B25759.1. ISSN 0016-7606.
- Erdman, Monica E.; Lee, Cin-Ty A.; Levander, Alan; Jiang, Hehe (April 2016). "Role of arc magmatism and lower crustal foundering in controlling elevation history of the Nevadaplano and Colorado Plateau: A case study of pyroxenitic lower crust from central Arizona, USA". Earth and Planetary Science Letters. 439: 48–57. Bibcode:2016E&PSL.439...48E. doi:10.1016/j.epsl.2016.01.032. ISSN 0012-821X.
- Ernst, W. G. (1 July 2009). "Rise and fall of the Nevadaplano". International Geology Review. 51 (7–8): 583–588. Bibcode:2009IGRv...51..583E. doi:10.1080/00206810903063315. ISSN 0020-6814. S2CID 129541879.
- Ernst, W.G. (1 April 2010). "Young convergent-margin orogens, climate, and crustal thickness—A Late Cretaceous–Paleogene Nevadaplano in the American Southwest?". Lithosphere. 2 (2): 67–75. Bibcode:2010Lsphe...2...67E. doi:10.1130/L84.1. ISSN 1941-8264.
- Henry, Christopher D.; Faulds, James E. (1 August 2010). "Ash-flow tuffs in the Nine Hill, Nevada, paleovalley and implications for tectonism and volcanism of the western Great Basin, USA". Geosphere. 6 (4): 339–369. Bibcode:2010Geosp...6..339H. doi:10.1130/GES00548.1. ISSN 1553-040X.
- Henry, Christopher D.; Hinz, Nicholas H.; Faulds, James E.; Colgan, Joseph P.; John, David A.; Brooks, Elwood R.; Cassel, Elizabeth J.; Garside, Larry J.; Davis, David A.; Castor, Steven B. (1 February 2012). "Eocene–Early Miocene paleotopography of the Sierra Nevada–Great Basin–Nevadaplano based on widespread ash-flow tuffs and paleovalleys". Geosphere. 8 (1): 1–27. Bibcode:2012Geosp...8....1H. doi:10.1130/GES00727.1. ISSN 1553-040X.
- Karlstrom, Karl E.; Jacobson, Carl E.; Sundell, Kurt E.; Eyster, Athena; Blakey, Ron; Ingersoll, Raymond V.; Mulder, Jacob A.; Young, Richard A.; Beard, L. Sue; Holland, Mark E.; Shuster, David L.; Winn, Carmen; Crossey, Laura (15 October 2020). "Evaluating the Shinumo-Sespe drainage connection: Arguments against the "old" (70–17 Ma) Grand Canyon models for Colorado Plateau drainage evolution". Geosphere. 16 (6): 1425–1456. Bibcode:2020Geosp..16.1425K. doi:10.1130/GES02265.1. hdl:2440/135048. ISSN 1553-040X. S2CID 228967384.
- Long, Sean P. (1 August 2012). "Magnitudes and spatial patterns of erosional exhumation in the Sevier hinterland, eastern Nevada and western Utah, USA: Insights from a Paleogene paleogeologic map". Geosphere. 8 (4): 881–901. doi:10.1130/GES00783.1. ISSN 1553-040X.
- Long, Sean P.; Soignard, Emmanuel (1 April 2016). "Shallow-crustal metamorphism during Late Cretaceous anatexis in the Sevier hinterland plateau: Peak temperature conditions from the Grant Range, eastern Nevada, U.S.A." Lithosphere. 8 (2): 150–164. Bibcode:2016Lsphe...8..150L. doi:10.1130/L501.1. ISSN 1941-8264.
- Smith, M. Elliot; Cassel, Elizabeth J.; Jicha, Brian R.; Singer, Brad S.; Canada, Andrew S. (December 2017). "Hinterland drainage closure and lake formation in response to middle Eocene Farallon slab removal, Nevada, U.S.A." Earth and Planetary Science Letters. 479: 156–169. Bibcode:2017E&PSL.479..156S. doi:10.1016/j.epsl.2017.09.023. ISSN 0012-821X.
- Lund Snee, Jens-Erik; Miller, Elizabeth L. (3 May 2022). "Magmatism, migrating topography, and the transition from Sevier shortening to Basin and Range extension, western United States". Tectonic Evolution of the Sevier-Laramide Hinterland, Thrust Belt, and Foreland, and Postorogenic Slab Rollback (180–20 Ma). pp. 335–357. doi:10.1130/2021.2555(13). ISBN 9780813725550. S2CID 244424493.
- Snell, Kathryn E.; Koch, Paul L.; Druschke, Peter; Foreman, Brady Z.; Eiler, John M. (January 2014). "High elevation of the 'Nevadaplano' during the Late Cretaceous". Earth and Planetary Science Letters. 386: 52–63. Bibcode:2014E&PSL.386...52S. doi:10.1016/j.epsl.2013.10.046. ISSN 0012-821X.
- Zuza, Andrew V.; Thorman, Charles H.; Henry, Christopher D.; Levy, Drew A.; Dee, Seth; Long, Sean P.; Sandberg, Charles A.; Soignard, Emmanuel (29 July 2020). "Pulsed Mesozoic Deformation in the Cordilleran Hinterland and Evolution of the Nevadaplano: Insights from the Pequop Mountains, NE Nevada". Lithosphere. 2020 (8850336). doi:10.2113/2020/8850336. ISSN 1941-8264. S2CID 225757790.