Mineralogical transformations set slow weathering rates in low-porosity metamorphic bedrock on mountain slopes in a tropical climate

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Autoren

  • Ricarda Behrens
  • Julien Bouchez
  • Jan A. Schuessler
  • Stefan Dultz
  • Tilak Hewawasam
  • Friedhelm Von Blanckenburg

Organisationseinheiten

Externe Organisationen

  • Helmholtz-Zentrum Potsdam Deutsches GeoForschungsZentrum (GFZ)
  • Universität Potsdam
  • Institut de Physique du Globe de Paris (IPGP)
  • University of Peradeniya
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Details

OriginalspracheEnglisch
Seiten (von - bis)283-298
Seitenumfang16
FachzeitschriftChemical geology
Jahrgang411
PublikationsstatusVeröffentlicht - 4 Sept. 2015

Abstract

In the Sri Lankan Highlands erosion and chemical weathering rates are among the lowest for global mountain denudation. In this tropical humid setting, highly weathered deep saprolite profiles have developed from high-grade metamorphic charnockite during spheroidal weathering of the bedrock. The spheroidal weathering produces rounded corestones and spalled rindlets at the rock-saprolite interface. We used detailed textural, mineralogical and chemical analyses to reconstruct the sequence of weathering reactions and their causes. The first mineral attacked by weathering was found to be pyroxene initiated by in situ Fe oxidation. Volumetric calculations suggest that this oxidation leads to the generation of porosity due to the formation of micro-fractures allowing for fluid transport and subsequent dissolution of biotite and plagioclase. The rapid ensuing plagioclase weathering leads to formation of high secondary porosity in the corestone over a distance of only a few cm and eventually to the final disaggregation of bedrock to saprolite. The first secondary phases are oxides or amorphous precipitates from which secondary minerals (mainly gibbsite, kaolinite and goethite) form. As oxidation is the first weathering reaction, the supply of O2 is a rate-limiting factor for chemical weathering. Hence, the supply of O2 and its consumption at depth connects processes at the weathering front with those at the Earth's surface in a feedback mechanism. The strength of the feedback depends on the relative weight of advective versus diffusive transport of O2 through the weathering profile. The feedback will be stronger with dominating diffusive transport. The low weathering rate is explained by the nature of this feedback that is ultimately dependent on the transport of O2 through the whole regolith, and on lithological factors such as low bedrock porosity and the amount of Fe-bearing primary minerals. Tectonic quiescence in this region and low pre-development erosion rate (attributed to a dense vegetation cover) minimize the rejuvenation of the thick and cohesive regolith column, finally leading to low denudation rates.

ASJC Scopus Sachgebiete

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Mineralogical transformations set slow weathering rates in low-porosity metamorphic bedrock on mountain slopes in a tropical climate. / Behrens, Ricarda; Bouchez, Julien; Schuessler, Jan A. et al.
in: Chemical geology, Jahrgang 411, 04.09.2015, S. 283-298.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Behrens R, Bouchez J, Schuessler JA, Dultz S, Hewawasam T, Von Blanckenburg F. Mineralogical transformations set slow weathering rates in low-porosity metamorphic bedrock on mountain slopes in a tropical climate. Chemical geology. 2015 Sep 4;411:283-298. doi: 10.1016/j.chemgeo.2015.07.008
Behrens, Ricarda ; Bouchez, Julien ; Schuessler, Jan A. et al. / Mineralogical transformations set slow weathering rates in low-porosity metamorphic bedrock on mountain slopes in a tropical climate. in: Chemical geology. 2015 ; Jahrgang 411. S. 283-298.
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title = "Mineralogical transformations set slow weathering rates in low-porosity metamorphic bedrock on mountain slopes in a tropical climate",
abstract = "In the Sri Lankan Highlands erosion and chemical weathering rates are among the lowest for global mountain denudation. In this tropical humid setting, highly weathered deep saprolite profiles have developed from high-grade metamorphic charnockite during spheroidal weathering of the bedrock. The spheroidal weathering produces rounded corestones and spalled rindlets at the rock-saprolite interface. We used detailed textural, mineralogical and chemical analyses to reconstruct the sequence of weathering reactions and their causes. The first mineral attacked by weathering was found to be pyroxene initiated by in situ Fe oxidation. Volumetric calculations suggest that this oxidation leads to the generation of porosity due to the formation of micro-fractures allowing for fluid transport and subsequent dissolution of biotite and plagioclase. The rapid ensuing plagioclase weathering leads to formation of high secondary porosity in the corestone over a distance of only a few cm and eventually to the final disaggregation of bedrock to saprolite. The first secondary phases are oxides or amorphous precipitates from which secondary minerals (mainly gibbsite, kaolinite and goethite) form. As oxidation is the first weathering reaction, the supply of O2 is a rate-limiting factor for chemical weathering. Hence, the supply of O2 and its consumption at depth connects processes at the weathering front with those at the Earth's surface in a feedback mechanism. The strength of the feedback depends on the relative weight of advective versus diffusive transport of O2 through the weathering profile. The feedback will be stronger with dominating diffusive transport. The low weathering rate is explained by the nature of this feedback that is ultimately dependent on the transport of O2 through the whole regolith, and on lithological factors such as low bedrock porosity and the amount of Fe-bearing primary minerals. Tectonic quiescence in this region and low pre-development erosion rate (attributed to a dense vegetation cover) minimize the rejuvenation of the thick and cohesive regolith column, finally leading to low denudation rates.",
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note = "Funding information: Stefan Gehrmann and Otto Diedrich are thanked for preparation of cylindrical samples from the corestone, and Tobias Meier and Eric Rybacki for their guidance with the He-pycnometry measurements. Thanks also go to Michael Klatt for support of laboratory work in Hannover, to Franziska Adams for help with Fe-redox analyses, and to Jean L. Dixon for sampling support. Dieter Rhede is acknowledged for electron microprobe analytical support and Geerke Floor and anonymous reviewers for comments on this manuscript. This work was conducted in the frame of the Graduate School GRK1364 funded by the German Science Foundation ( DFG ), co-financed by GFZ Potsdam , and the University of Potsdam .",
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Download

TY - JOUR

T1 - Mineralogical transformations set slow weathering rates in low-porosity metamorphic bedrock on mountain slopes in a tropical climate

AU - Behrens, Ricarda

AU - Bouchez, Julien

AU - Schuessler, Jan A.

AU - Dultz, Stefan

AU - Hewawasam, Tilak

AU - Von Blanckenburg, Friedhelm

N1 - Funding information: Stefan Gehrmann and Otto Diedrich are thanked for preparation of cylindrical samples from the corestone, and Tobias Meier and Eric Rybacki for their guidance with the He-pycnometry measurements. Thanks also go to Michael Klatt for support of laboratory work in Hannover, to Franziska Adams for help with Fe-redox analyses, and to Jean L. Dixon for sampling support. Dieter Rhede is acknowledged for electron microprobe analytical support and Geerke Floor and anonymous reviewers for comments on this manuscript. This work was conducted in the frame of the Graduate School GRK1364 funded by the German Science Foundation ( DFG ), co-financed by GFZ Potsdam , and the University of Potsdam .

PY - 2015/9/4

Y1 - 2015/9/4

N2 - In the Sri Lankan Highlands erosion and chemical weathering rates are among the lowest for global mountain denudation. In this tropical humid setting, highly weathered deep saprolite profiles have developed from high-grade metamorphic charnockite during spheroidal weathering of the bedrock. The spheroidal weathering produces rounded corestones and spalled rindlets at the rock-saprolite interface. We used detailed textural, mineralogical and chemical analyses to reconstruct the sequence of weathering reactions and their causes. The first mineral attacked by weathering was found to be pyroxene initiated by in situ Fe oxidation. Volumetric calculations suggest that this oxidation leads to the generation of porosity due to the formation of micro-fractures allowing for fluid transport and subsequent dissolution of biotite and plagioclase. The rapid ensuing plagioclase weathering leads to formation of high secondary porosity in the corestone over a distance of only a few cm and eventually to the final disaggregation of bedrock to saprolite. The first secondary phases are oxides or amorphous precipitates from which secondary minerals (mainly gibbsite, kaolinite and goethite) form. As oxidation is the first weathering reaction, the supply of O2 is a rate-limiting factor for chemical weathering. Hence, the supply of O2 and its consumption at depth connects processes at the weathering front with those at the Earth's surface in a feedback mechanism. The strength of the feedback depends on the relative weight of advective versus diffusive transport of O2 through the weathering profile. The feedback will be stronger with dominating diffusive transport. The low weathering rate is explained by the nature of this feedback that is ultimately dependent on the transport of O2 through the whole regolith, and on lithological factors such as low bedrock porosity and the amount of Fe-bearing primary minerals. Tectonic quiescence in this region and low pre-development erosion rate (attributed to a dense vegetation cover) minimize the rejuvenation of the thick and cohesive regolith column, finally leading to low denudation rates.

AB - In the Sri Lankan Highlands erosion and chemical weathering rates are among the lowest for global mountain denudation. In this tropical humid setting, highly weathered deep saprolite profiles have developed from high-grade metamorphic charnockite during spheroidal weathering of the bedrock. The spheroidal weathering produces rounded corestones and spalled rindlets at the rock-saprolite interface. We used detailed textural, mineralogical and chemical analyses to reconstruct the sequence of weathering reactions and their causes. The first mineral attacked by weathering was found to be pyroxene initiated by in situ Fe oxidation. Volumetric calculations suggest that this oxidation leads to the generation of porosity due to the formation of micro-fractures allowing for fluid transport and subsequent dissolution of biotite and plagioclase. The rapid ensuing plagioclase weathering leads to formation of high secondary porosity in the corestone over a distance of only a few cm and eventually to the final disaggregation of bedrock to saprolite. The first secondary phases are oxides or amorphous precipitates from which secondary minerals (mainly gibbsite, kaolinite and goethite) form. As oxidation is the first weathering reaction, the supply of O2 is a rate-limiting factor for chemical weathering. Hence, the supply of O2 and its consumption at depth connects processes at the weathering front with those at the Earth's surface in a feedback mechanism. The strength of the feedback depends on the relative weight of advective versus diffusive transport of O2 through the weathering profile. The feedback will be stronger with dominating diffusive transport. The low weathering rate is explained by the nature of this feedback that is ultimately dependent on the transport of O2 through the whole regolith, and on lithological factors such as low bedrock porosity and the amount of Fe-bearing primary minerals. Tectonic quiescence in this region and low pre-development erosion rate (attributed to a dense vegetation cover) minimize the rejuvenation of the thick and cohesive regolith column, finally leading to low denudation rates.

KW - Corestone

KW - Critical zone

KW - Regolith

KW - Sri Lanka

KW - Weathering

UR - http://www.scopus.com/inward/record.url?scp=84937501009&partnerID=8YFLogxK

U2 - 10.1016/j.chemgeo.2015.07.008

DO - 10.1016/j.chemgeo.2015.07.008

M3 - Article

AN - SCOPUS:84937501009

VL - 411

SP - 283

EP - 298

JO - Chemical geology

JF - Chemical geology

SN - 0009-2541

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