Latest Neoproterozoic to Mid-Cambrian age for the main deformation phases of the Transantarctic Mountains: new stratigraphic and isotopic constraints from the Pensacola Mountains, Antarctica

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Journal of the Geological Society; 2001; v. 158; issue.2; p. 295-308
© 2001 Geological Society of London

Regular Article

Latest Neoproterozoic to Mid-Cambrian age for the main deformation phases of the Transantarctic Mountains: new stratigraphic and isotopic constraints from the Pensacola Mountains, Antarctica

A. J. ROWELL, W. R. VAN SCHMUS, B. C. STOREY, A. H. FETTER & K. R. EVANS

¹ Museum of Natural History, Division of Invertebrate Paleontology and Department of Geology, University of Kansas, Lawrence, KS 66045, USA (e-mail: arowell{at}ukans.edu)
² Department of Geology, University of Kansas, Lawrence, KS 66045, USA
³ British Antarctic Survey, High Cross, Madingley Road, Cambridge CB3 0ET, UK

Scientific editing by Randall Parrish.

New isotopic ages and a fresh understanding of stratigraphicrelations among siliciclastic strata in the Pensacola Mountainsalong the northern margin of the East Antarctic craton resultin removal of some constraints for the Proterozoic break-upof Rodinia and necessitate revision of the subsequent historyof the East Antarctic margin. These rocks, formerly all includedin the Patuxent Formation, were thought to be of mid-Neoproterozoicage, to have formed as a consequence of Rodinia rifting, andto have been deformed during a Neoproterozoic orogenic event.Our data show, in contrast, that these siliciclastic stratawere deposited in two chronologically distinct basins. The olderbasin, in which the Hannah Ridge Formation (new name) accumulated,received sediment that contains detrital zircons of latest Neoproterozoicor Early Cambrian age. It was deformed and its contents upliftedand eroded prior to the late Mid-Cambrian in an orogenic eventthat we interpret as the early stage(s) of the Ross orogeny.The second basin formed later, accumulated turbidite-rich sedimentsof the redefined Patuxent Formation of Mid- and probably LateCambrian age, and was subsequently deformed, possibly in Ordoviciantime. Review of both biostratigraphic and isotopic ages alongthe length of the Transantarctic Mountains indicates that almosteverywhere the main episodes of deformation predate 500 Ma andare thus older than latest Mid-Cambrian, rather than Ordovician,as they are commonly considered to be. Only in the accretedBowers and Robertson Bay terranes of northern Victoria land,which reveal no clear record of pre-latest Mid-Cambrian or olderfolding, is the principal episode of Ross orogenic deformationdemonstrably younger than Late Cambrian.

Keywords: Cambrian, Neoproterozoic, Antarctica, orogeny, absolute age.

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