An Fe-Berthierine from a Cretaceous Laterite: Part II. Estimation of Eh, pH and pCO2 Conditions of Formation

Steven J. Fritz; Thomas A. Toth

doi:10.1346/CCMN.1997.0450409

Abstract

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Transgression by the Western Interior Sea during the Late Cretaceous in southwestern Minnesota caused swampy conditions to be imposed upon a laterite consisting of gibbsite, goethite and kaolinite. Reducing conditions overprinted upon the laterite reduced ferric Fe in goethite for incorporation of ferrous Fe into Fe-berthierine. Attendant oxidation of organic matter provided CO2 for siderite's formation. Thermodynamic calculations indicate that berthierine, gibbsite, goethite, kaolinite and siderite were in equilibrium with a solution whose pH was 5.2 and whose pCO2 was on the order of 0.3 atm. Formation of Fe-berthierine is favored by solutions having: 1) low silica concentration; 2) low [Mg2+]/[Fe2+] ratio; 3) high pCO2; 4) extremely low sulfate content before reduction takes place; and 5) moderate reducing conditions (Eh around −0.05 V).

References

Brookins, D.G., 1988 Eh-pH diagrams for geochemistry Berlin Springer-Verlag 10.1007/978-3-642-73093-1.CrossRef Google Scholar

Faure, G., 1991 Principles and applications of inorganic geochemistry New York Macmillan.Google Scholar

Flebbe, P.A. et al. , Cohen, 1984 et al. , Carbon dioxide and methane systematics in selected Okefenokee Swamp sites The Okefenokee Swamp Los Alamos, NM Wetland Surveys 380–390.Google Scholar

Kauffman, E.G., 1977 Geological and biological overview, Western Interior Basin Cretaceous facies, fauna, and paleoenvironments across the Western Interior Basin, Mountain Geologist. Rocky Mtn Assoc Geol 14 75–99.Google Scholar

Krauskopf, K., 1967 Introduction to geochemistry New York J Wiley.Google Scholar

Lindsay, W.L., 1979 Chemical equilibria in soils New York J Wiley.Google Scholar

Nordstrom, D.K. Valentine, S.D. Ball, J.W. Plummer, L.N. and Jones, B.E., 1984 Partial compilation and revision of basic data in the WATEQ programs US Geol Surv Water Res Invest 84–4186.Google Scholar

Postala, D., 1977 The Occurrence and chemical composition of recent Fe-rich mixed carbonates in a river bog J Sed Petrol 47 1089–1098.Google Scholar

Robie, R.A. Hemingway, B.S. and Fisher, J.R., 1979 Thermodynamic properties of minerals and related substances at 298.15 K and 1 bar (10⁵ Pascals) pressure and at higher temperatures US Geol Surv Bull 1452.Google Scholar

Stumm, W. and Morgan, J.J., 1981 Aquatic chemistry New York J Wiley.Google Scholar

Tardy, Y. and Garrels, R.M., 1974 A method of estimating the Gibbs energies of formation of layer silicates Geochim Cosmochim Acta 38 1101–1116 10.1016/0016-7037(74)90007-6.CrossRef Google Scholar

1982 J Phys Chem Ref Data 11 suppl2.Google Scholar

Woods, T.L. and Garrels, R.M., 1987 Thermodynamic values at low temperature for natural inorganic materials: An uncritical summary New York Oxford Univ Pr.Google Scholar

Weast, R.C. and Astle, W.J., 1981 editors. Handbook of Chemistry and Physics Boca Raton, FL CRC Pr.Google Scholar

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Hughes, R. E. Moore, D. M. Berres, T. E. and Farnsworth, K. B. 1998. Revision of hopewellian trading patterns in midwestern North America based on mineralogical sourcing*. Geoarchaeology, Vol. 13, Issue. 7, p. 709.

Moore, D. M. and Hughes, Randall E. 2000. Ordovician and Pennsylvanian Berthierine-Bearing Flint Clays. Clays and Clay Minerals, Vol. 48, Issue. 1, p. 145.

Aagaard, P. Jahren, J. S. Harstad, A. O. Nilsen, O. and Ramm, M. 2000. Formation of grain-coating chlorite in sandstones. Laboratory synthesized vs. natural occurrences. Clay Minerals, Vol. 35, Issue. 1, p. 261.

Drief, A. Nieto, F. and Sanchez-Navas, A. 2001. Experimental Clay-Mineral Formation from a Subvolcanic Rock by Interaction with 1 M NaOH Solution at Room Temperature. Clays and Clay Minerals, Vol. 49, Issue. 1, p. 92.

Sheldon, Nathan D. and Retallack, Gregory J. 2002. Low oxygen levels in earliest Triassic soils. Geology, Vol. 30, Issue. 10, p. 919.

Velde, B. 2003. Treatise on Geochemistry. p. 309.

Wilson, James Savage, David Cuadros, Javier Shibata, Masahiro and Ragnarsdottir, K.Vala 2006. The effect of iron on montmorillonite stability. (I) Background and thermodynamic considerations. Geochimica et Cosmochimica Acta, Vol. 70, Issue. 2, p. 306.

Bozzano, Francesca Gaeta, Mario and Marcoccia, Sabrina 2006. Weathering of Valle Ricca stiff and jointed clay. Engineering Geology, Vol. 84, Issue. 3-4, p. 161.

Sheldon, Nathan D. 2006. Precambrian paleosols and atmospheric CO2 levels. Precambrian Research, Vol. 147, Issue. 1-2, p. 148.

Wise, Michael A. 2007. Crystallization of ‘pocket’ berthierine from the Pulsifer granitic pegmatite, Poland, Maine, USA. Clays and Clay Minerals, Vol. 55, Issue. 6, p. 583.

Perronnet, Murielle Jullien, Michel Villiéras, Frédéric Raynal, Joël Bonnin, Dominique and Bruno, Gérard 2008. Evidence of a critical content in Fe(0) on FoCa7 bentonite reactivity at 80 °C. Applied Clay Science, Vol. 38, Issue. 3-4, p. 187.

Stel, Harry 2009. Diagenetic crystallization and oxidation of siderite in red bed (Buntsandstein) sediments from the Central Iberian Chain, Spain. Sedimentary Geology, Vol. 213, Issue. 3-4, p. 89.

Sheldon, Nathan D. and Tabor, Neil J. 2009. Quantitative paleoenvironmental and paleoclimatic reconstruction using paleosols. Earth-Science Reviews, Vol. 95, Issue. 1-2, p. 1.

Okwese, Ann C. Pe-Piper, Georgia and Piper, David J.W. 2012. Controls on regional variability in marine pore-water diagenesis below the seafloor in Upper Jurassic–Lower Cretaceous prodeltaic sandstone and shales, Scotian Basin, Eastern Canada. Marine and Petroleum Geology, Vol. 29, Issue. 1, p. 175.

French, Katherine L. Tosca, Nicholas J. Cao, Changqun and Summons, Roger E. 2012. Diagenetic and detrital origin of moretane anomalies through the Permian–Triassic boundary. Geochimica et Cosmochimica Acta, Vol. 84, Issue. , p. 104.

Samborska, Katarzyna Sitek, Sławomir Bottrell, Simon H. and Sracek, Ondra 2013. Modified Multi-phase Stability Diagrams: An AMD Case Study at a Site in Northumberland, UK. Mine Water and the Environment, Vol. 32, Issue. 3, p. 185.

Velde, B. 2014. Treatise on Geochemistry. p. 351.

Mu, Nana Schulz, Hans-Martin Fu, Yunjiao Schovsbo, Niels Hemmingsen Wirth, Richard Rhede, Dieter and van Berk, Wolfgang 2015. Berthierine formation in reservoir rocks from the Siri oilfield (Danish North Sea) as result of fluid–rock interactions: Part I. Characterization. Marine and Petroleum Geology, Vol. 65, Issue. , p. 302.

Wilson, James C. Benbow, Steven Sasamoto, Hiroshi Savage, David and Watson, Claire 2015. Thermodynamic and fully-coupled reactive transport models of a steel–bentonite interface. Applied Geochemistry, Vol. 61, Issue. , p. 10.

Fu, Yunjiao van Berk, Wolfgang Schulz, Hans-Martin and Mu, Nana 2015. Berthierine formation in reservoir rocks from the Siri oilfield (Danish North Sea) as result of fluid–rock interactions: Part II. Deciphering organic–inorganic processes by hydrogeochemical modeling. Marine and Petroleum Geology, Vol. 65, Issue. , p. 317.

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An Fe-Berthierine from a Cretaceous Laterite: Part II. Estimation of Eh, pH and pCO2 Conditions of Formation

Abstract

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References

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

An Fe-Berthierine from a Cretaceous Laterite: Part II. Estimation of Eh, pH and pCO2 Conditions of Formation

Abstract

Keywords

References

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