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Collisional Belts and Intra-Continental Convergence (A-type Subduction) |
1 Geology Department, Union College, Schenectady, NY 12308-2311, USA garverj{at}union.edu
2 Department of Geology and Geophysics, Yale University, P.O. Box 208109, 210 Whitney Avenue, New Haven, CT 06520-8109, USA
3 Earth and Environmental Sciences, State University of New York at Plattsburgh, Plattsburgh, NY, 12901, USA
4 Geochronology Research Unit, Earth Sciences Department, University of Waikato, Private Bag 3105, Hamilton, New Zealand
A relatively new field in provenance analysis is detrital fission-track thermochronology which utilizes grain ages from sediment shed off an orogen to elucidate its exhumational history. Four examples highlight the approach and usefulness of the technique. (1) Fission-track grain age (FTGA) distribution of apatite from modern sediment of the Bergell region of the Italian Alps corresponds to ages obtained from bedrock studies. Two distinct peak-age populations at 14.8 Ma and 19.8 Ma give calculated erosion rates identical to in situ bedrock. (2) Zircon FTGA distribution from the modern Indus River in Pakistan is used to estimate the mean erosion rate for the Indus River drainage basin to be about 560 m Ma–1, but locally it is in excess of 1000 m Ma–1. (3) FTGA distribution of detrital apatite and zircon from the Tofino basin records exhumation of the Coast Mountains in the Canadian Cordillera. Comparison of detrital zircon and apatite FT ages gives exhumation rates of c. 200 m Ma–1 during the interval between c. 34 and 54 Ma, but higher rates (c. 1500 m Ma–1) at c. 56 Ma. (4) FTGA analysis of apatite grain ages from a young basin flanking Fiordland in New Zealand indicates that removal of cover strata was followed by profound exhumation at c. 30 Ma, which corresponds to plate reorganization at this time. Exhumation rates at the onset of exhumation were c. 2000–5000 m Ma–1. These studies outline the technique of detrital FTGA applied to exhumation studies and highlight practical considerations: (1) well-dated, stratigraphically coordinated suites of samples that span the exhumation event provide the best long-term record; (2) strata from the basin perimeter are the most likely to retain unreset detrital ages; (3) the removal of ‘cover rocks’ precedes exhumation of deeply buried rocks, which retain a thermal signal of the exhumation event; (4) steady-state exhumation produces peak ages that progressively young with time and have a constant lag time; (5) same-sample comparison of zircon and apatite peak ages is best in sequences with high-uranium apatite grains (>50 ppm), and peak-ages statistics can be improved by counting numerous apatite grains (>100).
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  F. Lisker, B. Ventura, and U. A. Glasmacher Apatite thermochronology in modern geology Geological Society, London, Special Publications, 2009; 324: 1 - 23. [Abstract] [Full Text] [PDF]
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M. G. Malusa, M. Zattin, S. Ando, E. Garzanti, and G. Vezzoli Focused erosion in the Alps constrained by fission-track ages on detrital apatites Geological Society, London, Special Publications, 2009; 324: 141 - 152. [Abstract] [Full Text] [PDF]
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