Untangling inconsistent magnetic polarity records through an integrated rock magnetic analysis: A case study on Neogene sections in East Timor

Untangling inconsistent magnetic polarity records through an integrated rock magnetic analysis: A case study on Neogene sections in East Timor

Inconsistent polarity patterns in sediments are a common problem in magnetostratigraphic and paleomagnetic research. Multiple magnetic mineral generations result in such remanence “haystacks.” Here we test whether end‐member modeling of isothermal remanent magnetization acquisition curves as a basis...

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Veröffentlicht in:Geochemistry, geophysics, geosystems : G3 geophysics, geosystems : G3, 2014-06, Vol.15 (6), p.2531-2554
Hauptverfasser: Aben, F. M., Dekkers, M. J., Bakker, R. R., van Hinsbergen, D. J. J., Zachariasse, W. J., Tate, G. W., McQuarrie, N., Harris, R., Duffy, B.
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Schlagworte:
Case studies
East Timor
end-member modeling
Geophysics
greigite
Integrated approach
Magnetic fields
Magnetism
magnetite
Microscopic analysis
Microscopy
Mineralogy
Miocene
Neogene
Orogeny
Paleomagnetism
Pliocene
Polarity
remagnetization
Rivers
Rocks
Stratigraphy
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container_end_page 2554
container_issue 6
container_start_page 2531
container_title Geochemistry, geophysics, geosystems : G3
container_volume 15
creator Aben, F. M.
Dekkers, M. J.
Bakker, R. R.
van Hinsbergen, D. J. J.
Zachariasse, W. J.
Tate, G. W.
McQuarrie, N.
Harris, R.
Duffy, B.
description Inconsistent polarity patterns in sediments are a common problem in magnetostratigraphic and paleomagnetic research. Multiple magnetic mineral generations result in such remanence “haystacks.” Here we test whether end‐member modeling of isothermal remanent magnetization acquisition curves as a basis for an integrated rock magnetic and microscopic analysis is capable of isolating original magnetic polarity patterns. Uppermost Miocene‐Pliocene deep‐marine siliciclastics and limestones in East Timor, originally sampled to constrain the uplift history of the young Timor orogeny, serve as case study. An apparently straightforward polarity record was obtained that, however, proved impossible to reconcile with the associated biostratigraphy. Our analysis distinguished two magnetic end‐members for each section, which result from various greigite suites and a detrital magnetite suite. The latter yields largely viscous remanence signals and is deemed unsuited. The greigite suites are late diagenetic in the Cailaco River section and early diagenetic, thus reliable, in the Viqueque Type section. By selecting reliable sample levels based on a quality index, a revised polarity pattern of the latter section is obtained: consistent with the biostratigraphy and unequivocally correlatable to the Geomagnetic Polarity Time Scale. Although the Cailaco River section lacks a reliable magnetostratigraphy, it does record a significant postremagnetization tectonic rotation. Our results shows that the application of well‐designed rock magnetic research, based on the end‐member model and integrated with microscopy and paleomagnetic data, can unravel complex and seemingly inconsistent polarity patterns. We recommend this approach to assess the veracity of the polarity of strata with complex magnetic mineralogy. Key Points Use of IRM‐acquisition end‐member modeling for inconsistent polarity patterns Rock magnetism and microscopy separate primary from secondary magnetic carriers This integrated approach produces a reliable magnetostratigraphy
doi_str_mv 10.1002/2014GC005294
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An apparently straightforward polarity record was obtained that, however, proved impossible to reconcile with the associated biostratigraphy. Our analysis distinguished two magnetic end‐members for each section, which result from various greigite suites and a detrital magnetite suite. The latter yields largely viscous remanence signals and is deemed unsuited. The greigite suites are late diagenetic in the Cailaco River section and early diagenetic, thus reliable, in the Viqueque Type section. By selecting reliable sample levels based on a quality index, a revised polarity pattern of the latter section is obtained: consistent with the biostratigraphy and unequivocally correlatable to the Geomagnetic Polarity Time Scale. Although the Cailaco River section lacks a reliable magnetostratigraphy, it does record a significant postremagnetization tectonic rotation. 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By selecting reliable sample levels based on a quality index, a revised polarity pattern of the latter section is obtained: consistent with the biostratigraphy and unequivocally correlatable to the Geomagnetic Polarity Time Scale. Although the Cailaco River section lacks a reliable magnetostratigraphy, it does record a significant postremagnetization tectonic rotation. Our results shows that the application of well‐designed rock magnetic research, based on the end‐member model and integrated with microscopy and paleomagnetic data, can unravel complex and seemingly inconsistent polarity patterns. We recommend this approach to assess the veracity of the polarity of strata with complex magnetic mineralogy. 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Multiple magnetic mineral generations result in such remanence “haystacks.” Here we test whether end‐member modeling of isothermal remanent magnetization acquisition curves as a basis for an integrated rock magnetic and microscopic analysis is capable of isolating original magnetic polarity patterns. Uppermost Miocene‐Pliocene deep‐marine siliciclastics and limestones in East Timor, originally sampled to constrain the uplift history of the young Timor orogeny, serve as case study. An apparently straightforward polarity record was obtained that, however, proved impossible to reconcile with the associated biostratigraphy. Our analysis distinguished two magnetic end‐members for each section, which result from various greigite suites and a detrital magnetite suite. The latter yields largely viscous remanence signals and is deemed unsuited. The greigite suites are late diagenetic in the Cailaco River section and early diagenetic, thus reliable, in the Viqueque Type section. By selecting reliable sample levels based on a quality index, a revised polarity pattern of the latter section is obtained: consistent with the biostratigraphy and unequivocally correlatable to the Geomagnetic Polarity Time Scale. Although the Cailaco River section lacks a reliable magnetostratigraphy, it does record a significant postremagnetization tectonic rotation. Our results shows that the application of well‐designed rock magnetic research, based on the end‐member model and integrated with microscopy and paleomagnetic data, can unravel complex and seemingly inconsistent polarity patterns. We recommend this approach to assess the veracity of the polarity of strata with complex magnetic mineralogy. Key Points Use of IRM‐acquisition end‐member modeling for inconsistent polarity patterns Rock magnetism and microscopy separate primary from secondary magnetic carriers This integrated approach produces a reliable magnetostratigraphy</abstract><cop>Washington</cop><pub>Blackwell Publishing Ltd</pub><doi>10.1002/2014GC005294</doi><tpages>24</tpages><oa>free_for_read</oa></addata></record>
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subjects Case studies
East Timor
end-member modeling
Geophysics
greigite
Integrated approach
Magnetic fields
Magnetism
magnetite
Microscopic analysis
Microscopy
Mineralogy
Miocene
Neogene
Orogeny
Paleomagnetism
Pliocene
Polarity
remagnetization
Rivers
Rocks
Stratigraphy
title Untangling inconsistent magnetic polarity records through an integrated rock magnetic analysis: A case study on Neogene sections in East Timor
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