Charpentier, D. et al. (2011): Conditions and mechanism for the formation of iron-rich montmorillonite in deep-sea sediments (Costa Rica margin); coupling high-resolution mineralogical characterization and geochemical modeling

Leg/Site/Hole:
ODP 170
ODP 170 1039
Identifier:
2011-058744
georefid

10.1016/j.gca.2010.11.026
doi

Creator:
Charpentier, D.
Universite de Franche-Comte, Besancon, France
author

Buatier, M. D.
GEOKEMEX, France
author

Jacquot, E.
Universite de Nantes, France
author

Gaudin, A.
Moss Landing Marine Laboratories, United States
author

Wheat, C. G.
author

Identification:
Conditions and mechanism for the formation of iron-rich montmorillonite in deep-sea sediments (Costa Rica margin); coupling high-resolution mineralogical characterization and geochemical modeling
2011
Geochimica et Cosmochimica Acta
Elsevier, New York, NY, International
75
6
1397-1410
Iron-rich smectite is commonly described in the diagenetic fraction of deep-sea sediment, as millimeter to centimeter aggregates dispersed in the sediment, or as a coating on sedimentary particles or nodules. This study examines several factors to elucidate formation mechanisms of a particular iron-rich smectite and its potential transformation to glauconite. The study combines a detailed mineralogical investigation on natural samples and a chemical modeling approach to assess mineralogical reactions and pathways. Transmission electron microscopy (TEM) observations and analytical electron microscopy (TEM-AEM) analyses were conducted on microtomed samples of millimeter- to centimeter-long green grains. These grains are widespread in pelagic calcareous sediment from the Costa Rica margin. They are composed of pyrites that are partially dissolved and are surrounded by amorphous or very poorly crystallized iron-rich particles. Iron-rich montmorillonite grows from an amorphous precursor and its formation requires the input of Si, O, Mg, K, Na and Ca; our results suggest that these inputs are supported by the dissolution of sedimentary phases such as volcanic glasses, siliceous fossils and silicates. Thermodynamic modeling of fluid-sediment interactions was conducted with the geochemical computer code PhreeqC, using mineralogical and pore fluid compositions from sediment samples and calculated estimates for thermodynamic constants of smectites that are not maintained by the computer code. Simulations confirm the possibility that the green grains are the product of pyrite alteration by seawater under oxidizing conditions. The extent of smectite production is controlled by the kinetics of pyrite dissolution and fluid migration. The absence of aluminum in the Costa Rica margin system explains the formation of an iron-rich montmorillonite instead of glauconite, whereas the presence of calcite that buffers the system explains the formation of an iron-rich montmorillonite instead of iron oxides. Abstract Copyright (2011) Elsevier, B.V.
English
Serial
Coverage:Geographic coordinates:
North:9.3823
West:-86.1200East: -86.1200
South:9.3823

General geochemistry; Sedimentary petrology; aggregate; algae; alteration; calcareous composition; Central America; chemical composition; clay mineralogy; clay minerals; Coccolithophoraceae; continental margin; continental margin sedimentation; Costa Rica; crystal chemistry; deep-sea environment; diatoms; East Pacific; electron microscopy data; geochemistry; glauconite; high-resolution methods; hydrochemistry; Invertebrata; iron; Leg 170; marine environment; marine sediments; metals; mica group; microfossils; mineral composition; models; montmorillonite; nannofossils; Nicoya Peninsula; nodules; North Pacific; Northeast Pacific; Ocean Drilling Program; ODP Site 1039; oxidation; Pacific Ocean; pelagic environment; PHREEQC; Plantae; pore water; Protista; Radiolaria; sea water; sedimentary petrology; sedimentation; sediments; SEM data; sheet silicates; silicates; simulation; smectite; TEM data; X-ray diffraction data;

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