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New magnetostratigraphy and paleopole from the Whitmore Point Member of the Moenave Formation at Kanab, Utah

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The entire Whitmore Point Member of the Moenave Formation was sampled in close stratigraphic sequence (+0.3 m) from a vertical exposure in southwestern Utah. The polarity sequence in the Whitmore Point Member is essentially normal polarity, with five or more very short reversed intervals interspersed and a <1 m reversed interval at the top of the sequence. This polarity pattern dates the Whitmore Point Member as Hettangian. In the earliest Jurassic, the North American plate rotated even further westward from its Late Triassic position, and the movement appears to have been accompanied by an abrupt increase in plate motion because of the similarity in position of many Late Triassic paleopoles. The Moenave pole forms the ‘J-1 cusp’ of the North American apparent polar wander curve. The paleopole obtained by this study is somewhat further westward than those of previous studies. Within the 27 m of a mostly normal polarity sequence, the data show multiple, exceedingly short polarity intervals. The magnetization carrier is a maghemite-magnetite mineral, with the magnetization of an additional hematite carrier superposed. The lithostratigraphic sequence of the Moenave Formation is terminated by an unconformable surface, overlain by the Springdale Sandstone. Paleomagnetic directions of the Whitmore Point Member are exceedingly similar to those of the overlying Springdale Sandstone. Even though the two lithologic bodies are separated by a clear disconformity, the similarity in pole positions suggests that the two are closely related in time. It is possible that this disconformity represents the termination of the westward excursion of North America in earliest Jurassic time.The entire Whitmore Point Member of the Moenave Formation was sampled in close stratigraphic sequence (+0.3 m) from a vertical exposure in southwestern Utah. The polarity sequence in the Whitmore Point Member is essentially normal polarity, with five or more very short reversed intervals interspersed and a <1 m reversed interval at the top of the sequence. This polarity pattern dates the Whitmore Point Member as Hettangian. In the earliest Jurassic, the North American plate rotated even further westward from its Late Triassic position, and the movement appears to have been accompanied by an abrupt increase in plate motion because of the similarity in position of many Late Triassic paleopoles. The Moenave pole forms the ‘J-1 cusp’ of the North American apparent polar wander curve. The paleopole obtained by this study is somewhat further westward than those of previous studies. Within the 27 m of a mostly normal polarity sequence, the data show multiple, exceedingly short polarity intervals. The magnetization carrier is a maghemite-magnetite mineral, with the magnetization of an additional hematite carrier superposed. The lithostratigraphic sequence of the Moenave Formation is terminated by an unconformable surface, overlain by the Springdale Sandstone. Paleomagnetic directions of the Whitmore Point Member are exceedingly similar to those of the overlying Springdale Sandstone. Even though the two lithologic bodies are separated by a clear disconformity, the similarity in pole positions suggests that the two are closely related in time. It is possible that this disconformity represents the termination of the westward excursion of North America in earliest Jurassic time.
Czasopismo
Rocznik
Strony
13--22
Opis fizyczny
Bibliogr. 21 poz.
Twórcy
autor
  • Department of Geology and Geophysics, University of Wyoming, Laramie, Wyoming 82071, USA
Bibliografia
  • 1.Donohoo-Hurley L.L., Geissman J.W., Lucas S.G., 2010 — Magnetostratigraphy of the uppermost Triassic/lowermost Jurassic Moenave Formation, western USA, and correlation with strata in the United Kingdom, Morocco, Turkey, Italy and eastern USA. Geological Society of America Bulletin, 122: 2005–2019.
  • 2.Ekstrand E.J., Butler R.F., 1989 — Paleomagnetism of the Moenave Formation: implications for the Mesozoic North American apparent polar wander path. Geology, 17: 245–248.
  • 3.Gordon R.G., Cox A., O’Hare S., 1984 — Paleomagnetic Euler poles and the apparent polar wander and absolute motion of North America since the Carboniferous. Tectonics, 3: 499–537.
  • 4.Gradstein F.M., Ogg J.G., Schmidt M.D., Ogg G.M., 2012— The Geologic Time Scale, Vol. 2, Elsevier BV, Amsterdam.
  • 5.Harshbarger J.W., Repenning C.a., Irwin J.H., 1957 — Stratigraphy of the uppermost Triassic and Jurassic rocks of the Navajo Country. United States Geological Survey Professional Paper, 291.
  • 6.Hounslow M.W., Posen P., Warrington G., 2004 —Magnetostratigraphy of the uppermost Triassic and lowermost Jurassic succession, St. Audrie’s Bay, UK. Paleogeography, Paleoclimatology, Paleoecology, 213: 331–358.
  • 7.Kent D.V., Witte W.K., 1993 — Slow apparent polar wander for North America in the late Triassic and large Colorado Plateau rotation. Tectonics, 12.1: 291.
  • 8.Kirschvink J., 1980 — The least-squares line and plane and the analysis of palaeomagnetic data. Geophysical Journal, 62: 699–718.
  • 9.Lucas S.G., Milner A.R.C., 2006 — Conchostraca from the Lower Jurassic Whitmore Point Member of the Moenave Formation, Johnson Farm, southwestern Utah. New Mexico Museum of Natural History and Science Bulletin, 37: 421–423.
  • 10.Lucas S.G., Tanner L.H., 2007 — Tetrapod biostratigraphy and biochronology of the Triassic–Jurassic transition on the southern Colorado Plateau, USA. Palaeogeography, Palaeoclimatology, Palaeoecology, 244: 242–256.
  • 11.Lucas S.G., Tanner L.H., 2014 — Unconformable contact of the Lower Jurassic Wingate and Kayenta Formations, Utah. Utah Geological Association Publication, 43: 311–320.
  • 12.Lucas S.G., Tanner L.H, Donohoo-Hurley L.L., Geissman J.W., Kozur H.W., Heckert A.B., Weems R.E., 2011 — Position of the Triassic–Jurassic boundary and timing of the end-Triassic extinctions on land: Data from the Moenave Formation on the southern Colorado Plateau, USA. Palaeogeography, Palaeoclimatology, Palaeoecology, 302: 194–205.
  • 13.Molina-Garza R.S., Geissman J.W., Lucas S.G., 2003 — Paleomagnetism and magnetostratigraphy of the lower Glen Canyon and upper Chinle groups, Jurassic–Triassic of northern Arizona and northeastern Utah. Journal of Geophysical Research, 108 (B4): 2181; doi:10.1029/2002JB001909.
  • 14.Ogg J.G., 2012 — Triassic (Chapter 25). In: The Geologic Time Scale, Vol. 2 (eds F.M. Gradstein et al.): 681–730. Elsevier BV, Amsterdam.
  • 15.Ogg J.G., HinNov L.A., 2012 — Jurassic (Chapter 26). In: The Geologic Time Scale, Vol. 2 (eds F.M. Gradstein et al.): 731–791. Elsevier BV, Amsterdam.
  • 16.Reeve S.C., 1975 — Paleomagnetic studies of sedimentary rocks of Cambrian and Triassic age [Ph.D. dissertation,]. University of Texas at Dallas, Richardson.
  • 17.STEINER M., 2014 — Age of Lower Jurassic Springdale Sandstone of Southwestern Utah from its magnetic polarity sequence. Volumina Jurassica, 12, 2: 23–30 (this volume).
  • 18.Steiner M.B., Lucas S.G., 2000 — Paleomagnetism of the Late Triassic Petrified Forest Formation, Chinle Group, western United States: Further evidence for “large” rotation of the Colorado Plateau. Journal of Geophysical Research, 105: 25791–25808.
  • 19.Steiner M., Tanner L.H., 2014 — Magnetostratigraphy and paleopoles of the Kayenta Formation and the Tenney Canyon Tongue. Volumina Jurassica, 12, 2: 31–38 (this volume).
  • 20.Witte W.K., Kent D.V., Olsen P.E., 1991 — Magnetostratigraphy and paleomagnetic poles from Late Triassic–earliest Jurassic strata of the Newark Basin. Geological Society of America Bulletin, 103.12: 1648–1662.
  • 21.Yang Z., Moreau M.G., Bucher H.,Dommergues J.L., Trouiller A., 1996 — Hettangian and Sinemurian magnetostratigraphy from the Paris Basin. Journal of Geophysical Research, 101: 8025–8042
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-17f62af5-cba3-43b5-83ce-59003df0ee04
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