Downstream changes of alpine zircon fission-track ages in the Rhone and Rhine Rivers

Downstream changes of alpine zircon fission-track ages in the Rhone and Rhine Rivers

Zircons from 13 sediment samples from the Rhone and Rhine drainages were dated by the fission-track method to study down-stream changes in detrital fission-track grain-age distributions in large river systems draining the European Alps. The orogen-parallel Rhone River shows a zircon fission-track gr...

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Bibliographic Details
Published in:Journal of sedimentary research Vol. 74; no. 1; pp. 82 - 94
Main Authors: Bernet, Matthias, Brandon, Mark T, Garver, John I, Molitor, Brandi
Format: Journal Article
Language:English
Published: Society of Economic Paleontologists and Mineralogists 01-01-2004
Society for Sedimentary Geology
Subjects:
Alps
Cenozoic
clastic sediments
drainage basins
Earth Sciences
Environmental Sciences
Europe
fission tracks
fluvial sedimentation
Geochemistry
geochronology
Global Changes
Neogene
nesosilicates
orthosilicates
provenance
Rhine River
Rhone River
Sciences of the Universe
sed rocks, sediments
Sedimentary petrology
sedimentation
sediments
silicates
Tertiary
Western Alps
Western Europe
zircon
zircon group
France, Rhone R
Europe, Rhine R
detrital
Rhine River
zircon
fission-track
Rhône River
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Summary:Zircons from 13 sediment samples from the Rhone and Rhine drainages were dated by the fission-track method to study down-stream changes in detrital fission-track grain-age distributions in large river systems draining the European Alps. The orogen-parallel Rhone River shows a zircon fission-track grain-age distribution similar to that in its Alpine source areas. This signal is well preserved because there are Alpine sources along its full length and input from non-Alpine sources is small. In contrast, only the headwaters of the north-flowing Rhine River are located in the Alps. As a consequence, Alpine-derived zircons, which are distinguished by young fission-track ages, become progressively diluted downstream by older ages from zircon sources external to the Alps. Nevertheless, the Alpine component is persistent and can easily be detected in sediments more than 1000 km down-stream at the Rhine delta. These results demonstrate that fission-track dating of detrital zircons can provide useful information about orogenic processes, even where sediments have been transported hundreds of kilometers from the orogenic source, crossing ephemeral lakes and subsiding basins. Deposits along the lower reaches of the river appear to have a short-residence time (<1 Myr), and thus many of these deposits serve to smooth out variations in the supply of sediment from fast-eroding heterogeneous sources in the Alpine headwaters of these drainages. For the Rhone and the Rhine rivers, we show that fast erosion in the Alps accounts for most of the sediment load. This finding supports a widespread observation that the sediment in most large continental drainages is usually derived from a small part of the drain-age, where uplift, relief, and erosion rates are greatest.
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ISSN:1527-1404
DOI:10.1306/041003740082