Straight Cliffs Formation

The Straight Cliffs Formation is a stratigraphic unit in the Kaiparowits Plateau of south central Utah. It is Late Cretaceous (latest Turonian – early Campanian) in age and contains fluvial (river systems), paralic (swamps and lagoons), and marginal marine (shoreline) siliciclastic strata. It is well exposed around the margin of the Kaiparowits Plateau in the Grand Staircase – Escalante National Monument in south central Utah. The formation is named after the Straight Cliffs, a long band of cliffs creating the topographic feature Fiftymile Mountain.

Straight Cliffs Formation
Stratigraphic range: Late Cretaceous (Turonian to Campanian) 92–81 Ma
TypeGeological formation
UnderliesWahweap Formation
OverliesTropic Shale Formation
Thickness750 meters maximum
Lithology
PrimarySandstone
OtherSiltstone, Mudstone, coal, conglomerate
Location
RegionSouth central Utah
CountryUnited States
Extent3,600 km2
Type section
Named forStraight Cliffs
Named byGregory and Moore (1931)

The Straight Cliffs Formation was deposited in a marginal marine basin system along the western edge of the Cretaceous Western Interior Seaway. It is bounded below by the Tropic Shale and above by the Wahweap Formation. A variety of fossil species have been found within the Straight Cliffs including ammonites, mollusks, foraminifera, ostracods, sharks, fish, amphibians, turtles, lizards, crocodyliforms, dinosaurs, and mammals.

Geology

The Straight Cliffs Formation overlies the Cenomanian-Turonian Tropic Shale Formation and underlies the Campanian Wahweap Formation. It preserves fluvial and marginal marine strata from the Kaiparowits Basin of the Cretaceous Western Interior Seaway. The formation is primarily composed of sandstone and has lesser amounts of siltstones, mudstones, coals, and conglomerates. It is the partial lateral equivalent of the Mancos Shale formation further east. The Straight Cliffs Formation is latest Turonian to early Campanian in age.[1] The stratigraphy of the formation was initially studied for its coal resources and has more recently been studied as an analog for petroleum reservoirs. Consequently, the stratigraphy of the Straight Cliffs has been analyzed in detail.

Stratigraphy

The Straight Cliffs Formation was deposited in the Kaiparowits Basin of the Western Interior Seaway. The basin received sediment from the Mogollon highlands, the Sevier fold-thrust and the Cordilleran volcanic arc. The Mogollon highlands were mountains in central Arizona. The Sevier fold-thrust belt was a mountain range forming to the west of the Kaiparowits while the Cordilleran volcanic arc was further west in California. Although the Straight Cliffs Fm was deposited in an ancient basin it is preserved in a modern physiographic plateau. The Kaiparowits Plateau covers 3,600 km2 and preserves strata located roughly 120 km east of the leading edge of the thrust front at the time of deposition.[2] First analyzed for its coal content, the Straight Cliffs Formation was assessed by Gregory and Moore (1931)[3] and later by Peterson (1969a, 1969b)[4][5] and Vaninetti (1979).[6] The formation has four members in ascending order, the Tibbet Canyon Member, the Smoky Hollow Member, the John Henry Member and the Drip Tank Member.[5] The lithostratigraphy was first examined by Peterson, who broke the John Henry Member into seven sandstone intervals (A-F) and three coal zones. Shanley and McCabe (1991)[7] outlined sequence boundaries and systems tracts for the plateau based on the facies seen on the southern and eastern sides of the plateau. The formation is thought to represent the final transgression of the Tropic Sea.[8]

Shanley and McCabe (1991)[7] described two major sequence boundaries, which separate the Calico Bed from the underlying shales and the Drip Tank Member from the top of the John Henry Member. In addition they describe two minor sequence boundaries, one within the Tibbet Canyon Member while the other above the A-sandstone within the John Henry Member. Work done by Allen and Johnson (2010a, b, 2011)[9][10][11] in the Rogers Canyon area reassessed some of the interpretations made by Shanley and McCabe (1991)[7] and found multiple retrogradationally stacked parasequences creating overall transgressive-regressive cycles.

Tibbet Canyon Member

The Tibbet Canyon Member consists of shallow- marine, shoreface, and estuarine deposits.[12] It is well exposed in the southwestern and central parts of the Kaiparowits Plateau. The type locality of the Tibbet Canyon Member is near the mouth of Tibbet Canyon. It is about 70–185 ft thick and composed of yellow and gray very fine to medium sandstone.[5] The base of the unit is transitional into the underlying Tropic Shale, and the top of the member is marked by the contact with overlying mudstones and carbonaceous shales of the Smoky Hollow Member. The member is interpreted as beach and shallow marine deposits. As a whole, it is regressive and represents the withdrawal of the Tropic Sea.[13]

Smoky Hollow Member

The Smoky Hollow Member ranges from coal-bearing coastal plain strata to braided river strata. It is moderately well exposed along the southern margin of the plateau; however, it is often covered along the eastern Straight Cliffs escarpment.[5] The Smoky Hollow is 24 – 331 feet thick and increases in thickness in the northern corner of the plateau.[5] The top of the formation is distinguished by the Calico Bed, a braided fluvial unit, named for its white and orange coloring. The Calico Bed is a useful marker bed as it is present across the Kaiparowits Plateau and is easily distinguished in outcrop. The Smoky Hollow was deposited in non-marine environments, including lagoonal, coastal plain, and fluvial settings.

John Henry Member

The John Henry Member is the thickest of the four members of the Straight Cliffs. It contains strata that ranges from fluvial to marine. The lithologies seen include gray shales, siltstones, sandstones, carbonaceous shales, occasional coals and shell has beds. It ranges in thickness from 200 – 500 meters. The A – F sandstone intervals have been studied in detail on the eastern margin of the plateau[11][14] and can be correlated to fluvial units in the southwest and coastal plain coals in the center of the plateau.[15][16][4][7][6]

Drip Tank Member

The overlying Drip Tank Member consists of a coarse-grained fluvial facies thought to reflect a braided river environment. The base of the member often creates a bench at the top of the plateau. The upper contact of the Drip Tank grades into the Wahweap Formation creating sloped interval. The Drip Tank is 141 – 523 feet thick and is mainly composed of yellow to brown medium-grained cross stratified sandstone.

Depositional environment

The Straight Cliffs Formation was deposited in a variety of sub- environments that varied through time as the relative sea level of the Western Interior Seaway changed. The most basal member, the Tibbet Canyon, was deposited on the edge of the Greenhorn Seaway. The Tibbet Canyon preserves the shoreface sands deposited as the shoreline built out into the basin and the seaway retreated. The Smoky Hollow Member preserves fluvial and lagoonal deposits. It was deposited at a time when sea level was relatively low and the shoreline was east of the Kaiparowits Plateau.

The John Henry Member records fluctuations in the sea level. It contains interfingered marine and terrestrial deposits. In the southwestern region of the plateau the John Henry Member preserves ancient river systems which were carrying sediment into the basin from the uplifting Mogollon highlands and Sevier fold – thrust belt.[15][17] On the eastern side of the Kaiparowits Plateau the John Henry Member preserves interfingered marine and coastal deposits. Careful analysis of the stacking patterns within these beds suggests that the seaway was receding during the bottom third of the John Henry Member.[11] Sea level was rising and flooding the land during the middle portion of John Henry Member deposition.[11] Finally, the sea level fell again during the final phase of deposition.

A sequence boundary separates the Drip Tank Member from the underlying John Henry Member. This means that the strata of the uppermost John Henry Member were subaerially exposed and eroded before Drip Tank deposition. After the period of erosion river systems swept over the Kaiparowits Plateau and deposited the braided fluvial sheet deposits sands of the Drip Tank Member.

Paleontology

Invertebrate paleofauna

The most diverse and abundant fossils found in the Straight Cliffs Formation are invertebrate fauna. The fauna observed include oysters, ammonites, inoceramids, bivalves, ostracods and foraminifera. Oysters are one of the most common invertebrate fossils found in the Straight Cliffs Formation and are often preserved in large shell hash beds in marginal marine parts of the section.[18] Only the Tibbet Canyon and John Henry members are known to contain marine invertebrate fauna because the Smoky Hollow and Drip Tank Member were deposited in terrestrial settings.[8] The Tibbet Canyon Member was initially dated based a middle Turonian index fossil Inoceramus howelli which indicates the Prionocyclus hyatti ammonite zone.[13] A variety of invertebrate fossils have been found in the John Henry Member including the ammonite Baculites codyensis and the bivalve Endocostea baltica.[8] Analysis of foraminifera and ostracods has helped refine depositional environment interpretations for a variety of shallow marine sub-environments such as lagoons, bays, and estuaries[19][20]

GroupGenusSpeciesStratigraphicSource
PelecypodaInoceramusI.howelli WhiteTibbet Canyon MemberPeterson, 1969
PelecypodaInoceramusI. balticusJohn Henry MemberPeterson, 1969
PelecypodaInoceramussp.Tibbet Canyon Member, John Henry MemberPeterson, 1969
PelecypodaInoceramusI. Mesabiensis (Berquist)John Henry MemberPeterson, 1969
PelecypodaOstreasp.Tibbet Canyon MemberPeterson, 1969
PelecypodaOstreaO. congesta ConradJohn Henry MemberPeterson, 1969
PelecypodaCrassostreaC. soleniscus (Meek)Tibbet Canyon Member, John Henry MemberPeterson, 1969
PelecypodaCrassostreaC. coalvillensis (Meek)John Henry MemberPeterson, 1969
PelecypodaBrachidontessp.Tibbet Canyon Member, John Henry MemberPeterson, 1969
PelecypodaCardium cf.C. pauperculum MeekTibbet Canyon MemberPeterson, 1969
PelecypodaLegumen cf.L. ellipticum ConradTibbet Canyon MemberPeterson, 1969
GastropodaGyrodesG. conradi MeekTibbet Canyon MemberPeterson, 1969
GastropodaGyrodesG. depressus MeekExamplePeterson, 1969
GastropodaCryptorhytisC. utahensis (Meek)Tibbet Canyon MemberPeterson, 1969
CephalopodaHeterotissotiasp.Tibbet Canyon MemberPeterson, 1969
CephalopodaBaculitesB. asper MortonJohn Henry MemberPeterson, 1969
CephalopodaBaculitesB. codyensisJohn Henry MemberPeterson, 1969
CephalopodaProtexanitesP. shoshonensis (Meek)John Henry MemberPeterson, 1969
CephalopodaPlacenticerassp.John Henry MemberPeterson, 1969
CephalopodaScaphitessp.John Henry MemberPeterson, 1969
AnnelidaSerpula cf.S. tenuicarinataJohn Henry MemberPeterson, 1969

Vertebrate fossils

Vertebrate fossils have been found throughout the Straight Cliffs Formation. The fossils from the Straight Cliffs Formation document a diverse assemblage of therian mammals.[21][22] The Tibbet Canyon Member contains sharks’ teeth from marine deposits rare mammal fossils from deltaic deposits.[22] Recovered fossils include sharks, rays, lepisosteid fishes, crocodyliforms, and fragmentary marsupial mammal teeth.[22] The Smoky Hollow Member also contains a variety of sharks, amphibians, reptiles, snakes, crocodyliforms, and dinosaurs. The member also contains multituberculate and marsupial mammals. The John Henry Member contains more brackish and marine fauna, as well as mammals and other terrestrial species which are less common.[22] The Drip Tank Member is primarily fluvial and consequently only water worn fragments of turtle and crocodyliforms have been recovered.[22]

GroupGenusSpeciesStratigraphic PositionMaterialSource
ChondrichthyesScapanorhynchusS. raphiodon (Agassiz)Tibbet Canyon MemberPeterson, 1969
ChondrichthyesLamnaL. appendiculata AgassizJohn Henry MemberPeterson, 1969
ChondrichthyesChiloscylliumC. grenniTibbet Canyon MemberEaton et al., 1999
ChondrichthyesSqualicoraxS. falcatusTibbet Canyon MemberEaton et al., 1999
ChondrichthyesCretodusC. semiplicatusTibbet Canyon MemberEaton et al., 1999 (wrongly attributed to "Ceratodus semiplicatus")
ChondrichthyesPhychodussp.John Henry MemberPeterson, 1969
ChondrichthyesLissodussp.John Henry MemberEaton et al., 1999
ChondrichthyesHybodussp.John Henry MemberEaton et al., 1999
ChondrichthyesPtychodusP. mortoni Agassiz, 1843John Henry MemberEaton et al., 1999
ChondrichthyesUndifferentiatedJohn Henry MemberTeeth fragmentsPeterson, 1969
OsteichthyesLepisosteussp.John Henry MemberEaton et al., 1999
OsteichthyesAtractosteussp.John Henry MemberEaton et al., 1999
UrodelaAlbanerpetonsp.John Henry MemberEaton et al., 1999
TestudinesAdocussp.John Henry MemberEaton et al., 1999
TestudinesAspideretessp.John Henry MemberEaton et al., 1999
TestudinesBasilemyssp.John Henry MemberEaton et al., 1999
TestudinesNaomichelyssp.John Henry MemberEaton et al., 1999
SquamataOdaxosaurusO. piger (Gilmore, 1928)John Henry MemberEaton et al., 1999
CrocodyliaBernissartiasp.John Henry MemberEaton et al., 1999
CrocodyliaMesoeucrocodyliaIrmis et al., 2013
CrocodyliaNeosuchiaIrmis et al., 2013
TestudinesUndifferentiatedJohn Henry MemberCarapace fragmentsEaton et al., 1999
MultituberculataCimolodonC. foxiJohn Henry Member
MultituberculataCimolodonC. similisJohn Henry MemberEaton, 2013
MultituberculataParacimexomyssp.John Henry Member, Smoky Hollow MemberEaton et al., 1999
MultituberculataSymmetrodontoidesS. oligodontosSmoky Hollow MemberCefelli, 1990
MultituberculataSymmetrodontoidesS. mckennaiSmoky Hollow MemberCefelli, 1990
MultituberculataCedaromyssp.Tibbet Canyon Member, John Henry MemberEaton, 2006
MultituberculataMesodmasp.John Henry MemberEaton, 2013
MultituberculataDakotamysD. shakespeariJohn Henry MemberEaton, 2013
MultituberculataBryceomysB. fumosusSmoky Hollow MemberEaton, 1995
Multituberculata BryceomysB. hadrosusSmoky Hollow MemberEaton, 1995
MarsupialiaSpalacotheridiumsp.John Henry MemberCifelli, 1990
MarsupialiaFamily PeradectidaeIndet.John Henry MemberEaton et al., 1999
MarsupialiaFamily StagodontidaeIndet.John Henry MemberEaton et al., 1999
MarsupialiaAlphadonsp.John Henry MemberEaton, 2006
MarsupialiaApistodonsp.John Henry MemberEaton, 2013
MarsupialiaVaralphadonsp.Smoky Hollow Member, John Henry MemberEaton, 2006
MarsupialiaEodelphissp.John Henry MemberCifelli, 1990
MarsupialiaLeptalestessp.John Henry MemberEaton, 2013
DinosauriaRichardoestesiaR. gilmoreiJohn Henry MemberEaton, 2013
FishDiplomystussp.John Henry MemberTeethLarson and Currie, 2013
FishLepisosteidsp.Smoky Hollow Member, John Henry MemberTeeth fragmentsBrinkman et al., 2013
FishMicropycnodonsp.John Henry MemberTeeth fragmentsBrinkman et al., 2013
FishAmiidaesp.Smoky Hollow Member, John Henry MemberBrinkman et al., 2013
FishMelviussp.John Henry MemberTeeth and centraBrinkman et al., 2013
FishOstariophysasp.John Henry MemberCentraBrinkman et al., 2013
FishTeleost typeSmoky Hollow Member, John Henry MemberCentraBrinkman et al., 2013
FishAcanthopterygianJohn Henry MemberCentraBrinkman et al., 2013
FishHiodontidSmoky Hollow Member, John Henry MemberBrinkman et al., 2013
FishElopomorphSmoky Hollow Member, John Henry MemberBrinkman et al., 2013
gollark: What's a v- gollark?
gollark: ↓ gibson
gollark: By randomly gluing together helpful proteins from known life and using a "nanopore" thing as is used for DNA, they can things.
gollark: It's a methodology for seeing what amino acids proteins contain.
gollark: https://www.science.org/content/blog-post/thread-your-proteins-through

See also

References

  1. Szwarc, Tyler S., Johnson, Cari L., Stright, Lisa E., McFarlane, Christopher M., In revision, Interactions between axial and transverse drainage systems in the Late Cretaceous Cordilleran foreland basin: Evidence from detrital zircons in the Straight Cliffs Formation, southern Utah, USA: GSA Bulletin, September 2014
  2. Shanley, K. W., and McCabe, P. J., 1995, Sequence stratigraphy of Turonian-Santonian strata, Kaiparowits Plateau, southern Utah, USA: Implications for regional correlation and foreland basin evolution, in Van Wagoner, J. C., and Bertram, G. T., eds., Sequence Stratigraphy of Foreland Basin Deposits, Volume AAPG Memoir 64.
  3. Gregory, H. E., and Moore, R. C., 1931, The Kaiparowits Region: a geographic and geologic reconnaissance of parts of Utah and Arizona, in Interior, U. S. D. o. t., ed., USGS Survey Professional Paper 164: Washington D.C., p. 161.
  4. Peterson, F., 1969a, Cretaceous sedimentation and tectonism in the southeastern Kaiparowits region, Utah, in United States Department of the Interior, G. S., ed., Volume Open-file Report 60-167.
  5. Peterson, F., 1969b, Four new members of the upper Cretaceous Straight Cliffs Formation in the southeastern Kaiparowits region, Kane County, Utah: Geological Survey Bulletin, no. 1274-J, p. J1-J28.
  6. Vaninetti, G. E., 1979, Coal stratigraphy of the John Henry Member of the Straight Cliffs Formation, Kaiparowits Plateau, Utah [M.S.: University of Utah].
  7. Shanley, K. W., and McCabe, P. J., 1991, Predicting facies architecture through sequence stratigraphy -- An example from the Kaiparowits Plateau, Utah: Geology, v. 19, p. 742-745.
  8. Cobban, W. A., Dyman, T. S., Pollock, G. L., Takahashi, K. I., Davis, L. E., and Riggin, D. B., 2000, Inventory of dominantly marine and brackish-water fossils from Late Cretaceous rocks in and near Grand Staircase-Escalante National Monument, Utah, in Sprinkel, D. A., Chidsey, T. C., and Anderson, P. B., eds., Geology of Utah's Parks and Monuments, Volume 2000 Utah Geological Association Publication 28.
  9. Allen, J. L., and Johnson, C. L., 2010, Facies control on sandstone composition (and influence of statistical methods on interpretations) in the John Henry Member, Straight Cliffs Formation, southern Utah, USA: Sedimentary Geology, v. 230, no. 1-2, p. 60-76.
  10. Allen, J. L., and Johnson, C. L., 2010, Sedimentary facies, paleoenvironments and relative sea level changes in the John Henry Member, Cretaceous Straight Cliffs Formation, Southern Utah, USA in Carney, S. M., Tabet, D. E., and Johnson, C. L., eds., Geology of South-Central Utah, Volume 39: Salt Lake City, Utah Geological Association Publication.
  11. Allen, J. L., and Johnson, C. L., 2011, Architecture and formation of transgressive-regressive cycles in marginal marine strata of the John Henry Member, Straight Cliffs Formation, Upper Cretaceous of Southern Utah, USA: Sedimentology, v. 58, no. 6, p. 1486-1513.
  12. Hettinger, R. D., 2000, Chapter J: A Summary of Coal Distribution and Geology in the Kaiparowits Plateau, Utah, in Kirschbaum, M. A., Roberts, L. N. R., and Biewick, L. R. H., eds., Geologic Assessment of Coal in the Colorado Plateau: Arizona, Colorado, New Mexico, and Utah, Volume U.S. Geological Survey Professional Paper 1625–B.
  13. Eaton, J. G., 1991, Biostratigraphic framework for the Upper Cretaceous rocks of the Kaiparowits Plateau, southern Utah, in Nations, J. D., and Eaton, J. G., eds., Stratigraphy, depositional environments, and sedimentary tectonics of the western margin, Cretaceous Western Interior Seaway: Geological Society of America Special Paper 260, p. 47-63.
  14. Dooling, P., 2012, Tidal facies, stratigraphic architecture, and along-strike variability of a high energy, transgressive shoreline, late Cretaceous, Kaiparowits, Plateau, southern Utah [M.S.: University of Utah].
  15. Gallin, W. N., Johnson, C. L., and Allen, J. L., 2010, Fluvial and marginal Marine Architecture of the John Henry Member, Straight Cliffs Formation, Kelly Grade of the Kaiparowits Plateau, South-Central Utah, in Carney, S. M., Tabet, D. E., and Johnson, C. L., eds., Geology of South-Central Utah, Volume 39: Salt Lake City, Utah Geological Association
  16. Gooley, J., 2010, Alluvial Architecture and Predictive Modeling of the Late Cretaceous John Henry Member, Straight Cliffs Formation, Southern Utah [M.S.: University of Utah].
  17. Szwarc, Tyler S., Johnson, Cari L., Stright, Lisa E., McFarlane, Christopher M., In revision, Interactions between axial and transverse drainage systems in the Late Cretaceous Cordilleran foreland basin: Evidence from detrital zircons in the Straight Cliffs Formation, southern Utah, USA: GSA Bulletin.
  18. Titus, A., Powell, J. D., Roberts, E. M., Sampson, S. D., Pollock, S. L., Kirkland, J. I., and Albright, L. B., 2005, Late Cretaceous stratigraphy, depositional environments, and macrovertebrate paleontology of the Kaiparowits Plateau, Grand Staircase-Escalante National Monument, Utah, in Pederson, J., and Dehler, C. M., eds., Interior Western United States: Geological Society of America Field Guide 6 p. 101-128.
  19. Tibert, N. E., Colin, J.-P., and Leckie, R. M., 2009, Taxonomy, biostratigraphy and paleoecology of Cenomanian and Turonian ostracodes from the Western Interior Basin, Southwest Utah, USA: Revue de Micropaléontologie, v. 52, no. 2, p. 85-105.
  20. Tibert, N. E., and Leckie, R. M., 2004, High-resolution estuary sea level cycles from the Late Cretaceous: amplitude constraints using agglutinated foraminifera: Journal of Foraminiferal Research, v. 34, no. 2, p. 130-143.
  21. Eaton, J. G., 1987, The Campanian-Maastrichtian boundary in the Western Interior of North America: Newsletters on Stratigraphy, v. 18, no. 1, p. 31-39.
  22. Eaton, J. G., Cifelli, R. L., Hutchison, J. H., Kirkland, J. I., and Parrish, M. J., 1999, Cretaceous vertebrate faunas from the Kaiparowits Plateau, south-central Utah: Utah Geological Survey Miscellaneous Publication, v. 99-1.
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