(Table 1) Apatite fission track (AFT) data of the Eisenhower Range

The Transantarctic Mountains (TAM) were one of the first regions where apatite fission track (AFT) thermochronology was applied routinely to study exhumation processes and long term landscape evolution. Pioneering publications from the region introduced or refined interpretation concepts of thermoch...

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Bibliographic Details
Main Authors: Prenzel, Jannis, Lisker, Frank, Balestrieri, Maria Laura, Läufer, Andreas, Spiegel, Cornelia
Format: Dataset
Language:English
Published: PANGAEA 2016
Subjects:
Age
dated
dated standard deviation
Antarctica
Area/locality
Diameter
Elevation of event
Event label
Fission-track length
mean
standard deviation
Fission-tracks
density
counted in stan
induced
spontaneous
GANOVEX_IX
Goodness of fit
Grains
counted/analyzed
ItalAnt_C1
ItalAnt_C17
ItalAnt_C3
ItalAnt_C4
ItalAnt_C5
ItalAnt_C6
ItalAnt_C9
Latitude of event
Longitude of event
Number
Number of observations
Percentage
Priority Programme 1158 Antarctic Research with Comparable Investigations in Arctic Sea Ice Areas
ROCK
Rock sample
Samp_3462
Samp_3463
Samp_3464
Antarc*
Antarctic
Sea ice
Online Access:https://doi.pangaea.de/10.1594/PANGAEA.868499
https://doi.org/10.1594/PANGAEA.868499
Description
Summary:The Transantarctic Mountains (TAM) were one of the first regions where apatite fission track (AFT) thermochronology was applied routinely to study exhumation processes and long term landscape evolution. Pioneering publications from the region introduced or refined interpretation concepts of thermochronological data such as the break in slope in vertical age profiles as qualitative marker for the onset of accelerated rock cooling. New AFT data were compiled from vertical profiles in the Eisenhower Range, northern TAM, and compared with published data. Samples originally examined by population technique were re-analysed via the external detector technique. AFT ages increase from 32±2 Ma at an elevation of 220 m to 175±14 Ma at 2380 m. Geological evidence and thermal history modeling of the AFT data require Jurassic to Late Eocene reheating of the samples and an onset of cooling at ~35 - 30 Ma. This requires the deposition of a ~3 to 3.5 km thick sedimentary sequence on the granitic basement subsequent to Jurassic Ferrar magmatism at ~180 Ma. The regression of paleotemperatures against sample altitudes infers a high Jurassic geothermal gradient of ~60°C/km related to rifting processes and Ferrar magmatism, and a moderate Cretaceous/Eocene geothermal gradient of ~30°C/km. Comparison of ages generated with population and external detector technique shows the importance of determining single-grain ages for each sample, even from granitic rocks of the same intrusion, and thus strongly supports previous cases made for the determination of annealing kinetics and grain-age evaluation. Age comparison additionally illustrates, that samples above a break in slope record larger deviations between population and external detector ages than samples below a break in slope. We demonstrate that position and shape of a break in slope result from various factors, such as the thermal history prior to final cooling, maximum paleotemperatures, cooling rate, and geothermal gradient. A break in slope does not straightly date the onset of ...

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