TY - JOUR
T1 - Detrital zircon provenance of Permo-Carboniferous glacial diamictites across Gondwana
AU - Craddock, John P.
AU - Ojakangas, Richard W.
AU - Malone, David H.
AU - Konstantinou, Alexandros
AU - Mory, Arthur
AU - Bauer, Wilfried
AU - Thomas, Robert J.
AU - Affinati, Suzanne Craddock
AU - Pauls, Kathryn
AU - Zimmerman, Udo
AU - Botha, Greg
AU - Rochas-Campos, Anthony
AU - Santos, Paulo R.dos
AU - Tohver, Eric
AU - Riccomini, Claudio
AU - Martin, Joe
AU - Redfern, Jonathan
AU - Horstwood, Matthew
AU - Gehrels, George
N1 - Funding Information: Craddock and Ojakangas started this project in the Ellsworth Mountains (1979-80) and progressed with piecemeal funding. Tohver acknowledges Australian Research Council grant LP0991834 , and Riccomini Brazilian Council for Scientific and Technological Development grant CNPQ 307871/2010-0 . Nancy Vickery and Bob Brown are thanked for contributing samples from eastern Australia. Macalester students who participated in this effort were: Alex Nereson, Maria Princen, Nick Culter, Dale Dybvig, Jesse Geary and Jake Moen. Matthew Horstwood (NERC Lab, U.K.) is thanked for aiding the analysis of the Canning Basin detrital zircons. We thank Petroleum Development Oman and especially Irene Gomez Perez for the drill cores from the Al Khlata Formation. The sample material for our study was released by the Ministry of Oil and Gas of the Sultanate of Oman (MOG Ref. 7312/12531) which is gratefully acknowledged. Martin and Redfern acknowledge the joint financial support provided by Natural Environment Research Council (UK) Studentship NER/S/A/2004/13012. Gerhard Spaeth kindly contributed the Heimefront Range field photo and Jim Collinson contributed TAM field images. A. J. Mory publishes with the permission of the Director, Geoscience Resources Strategy. The Laserchron crew at the University of Arizona was awesome over many decades! Pucks containing the detrital zircons analyzed in this study, except the Canning Basin, Australia (contact Jonathan Redfern, University of Manchester) and Sites 23 and 24 (contact the Laserschron Center, University of Arizona), will be housed at the Byrd Polar Research Center, Ohio State University, for future use. Doug Cole and one anonymous reviewer greatly improved the clarity and presentation of the manuscript. Publisher Copyright: © 2019
PY - 2019/5
Y1 - 2019/5
N2 - Gondwana changed its high latitude location during the late Paleozoic (338–265 Ma), relative to the South Pole, and the style of glaciation evolved from localized alpine glaciers and ice fields to ~30 small ice sheets across the supercontinent. We report the analysis of heavy mineral populations (n = 2217) and the ages of detrital zircons (n = 2920 U-Pb LA-ICPMS results) from Gondwana diamictite deposits from eight landmasses: Africa (5 samples), Antarctica (5), Australia (8), the Ellsworth Mountains terrane (1, Antarctica), the Falkland Islands (2, diamictite plus U-Pb SHRIMP ages on granite clasts), India (1), Madagascar (1), Oman (3), the equatorial Lhasa terrane (2), the equatorial North Qiantang terrane (2) and South America (10). Heavy mineral separations (SEM-WDS analysis) identified one anomaly, pyrope garnets present only in Dwyka Group and Dwyka-equivalent samples suggesting an ultramafic Antarctic source. Statistical analysis of detrital zircon age distributions support the inference of local transport of sediment from many small ice centers with five examples of far-field ice transport (>1000 km; four with ice flow >2000 km), and three from ice fields located along coastal Antarctica. We propose that ice was distributed from five main ice-caps of different ages in southern Gondwana with ice flow away from central Gondwana. We also confirm that the Permo-Carboniferous detrital zircon populations of Euramerica (eolian and fluvial) and Gondwana (ash, detrital-glacial) are not mixed across the equator or seaway and ponder the possibility of a late Paleozoic snowball Earth.
AB - Gondwana changed its high latitude location during the late Paleozoic (338–265 Ma), relative to the South Pole, and the style of glaciation evolved from localized alpine glaciers and ice fields to ~30 small ice sheets across the supercontinent. We report the analysis of heavy mineral populations (n = 2217) and the ages of detrital zircons (n = 2920 U-Pb LA-ICPMS results) from Gondwana diamictite deposits from eight landmasses: Africa (5 samples), Antarctica (5), Australia (8), the Ellsworth Mountains terrane (1, Antarctica), the Falkland Islands (2, diamictite plus U-Pb SHRIMP ages on granite clasts), India (1), Madagascar (1), Oman (3), the equatorial Lhasa terrane (2), the equatorial North Qiantang terrane (2) and South America (10). Heavy mineral separations (SEM-WDS analysis) identified one anomaly, pyrope garnets present only in Dwyka Group and Dwyka-equivalent samples suggesting an ultramafic Antarctic source. Statistical analysis of detrital zircon age distributions support the inference of local transport of sediment from many small ice centers with five examples of far-field ice transport (>1000 km; four with ice flow >2000 km), and three from ice fields located along coastal Antarctica. We propose that ice was distributed from five main ice-caps of different ages in southern Gondwana with ice flow away from central Gondwana. We also confirm that the Permo-Carboniferous detrital zircon populations of Euramerica (eolian and fluvial) and Gondwana (ash, detrital-glacial) are not mixed across the equator or seaway and ponder the possibility of a late Paleozoic snowball Earth.
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U2 - 10.1016/j.earscirev.2019.01.014
DO - 10.1016/j.earscirev.2019.01.014
M3 - Review article
SN - 0012-8252
VL - 192
SP - 285
EP - 316
JO - Earth-Science Reviews
JF - Earth-Science Reviews
ER -