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New insights into smectite illitization: A zoned K-bentonite revisited

  • Douglas K. McCarty EMAIL logo , Boris A. Sakharov and Victor A. Drits
Published/Copyright: April 1, 2015
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American Mineralogist
From the journal American Mineralogist Volume 94 Issue 11-12

Abstract

The illitization reaction in a thick K-bentonite bed located in upper Cretaceous marine shale in the Montana disturbed belt was studied by X-ray diffraction, chemical analysis, and thermal gravimetric analysis. Modeling of the experimental XRD patterns from oriented clay specimens in air-dried and glycolated states shows that at each sample location in the bentonite bed a mixture of R0 illite-smectite (I-S) and R1 I-S coexist. Each of these phases in all samples consists of the same or similar content of illite and expandable layers independent on location in the bed. In particular, the illite content in the R0 I-S and the R1 I-S from the <0.5 μm fractions is equal to 30 and 62%, respectively. The main difference between the samples at different locations is the different weight concentrations of the coexisting I-S phases. The R1 I-S content decreases progressively from the lower and upper contacts of the bed to its center. The reverse trend was observed for the R0 I-S. The layer unit-cell parameter b increases from samples located near the middle of the bed toward samples near the bed margins. The DTG patterns of the samples contain two endothermic maxima at about 640 and 470 °C, corresponding to cis-vacant (cv) illite and trans-vacant (tv) smectite layers coexisting in the R1 I-S and R0 I-S.

Analysis of the crystal-chemical features of the R1 I-S and R0 I-S shows that, in the middle of the bed, both phases are characterized by the lowest octahedral Mg and the highest tetrahedral Al contents. In the structural formula of the R1 I-S, the tetrahedral Al content is significantly higher than the (K+Na) content independent of sample location. In contrast, tetrahedral Al in the R0 I-S located near the bed boundaries is lower compared with (K+Na) content.

To account for the crystal-chemical features of the coexisting I-S, a first assumption is that the initial volcanic ash was altered into tv smectite having a homogeneous Al-rich composition throughout the bed. Second, along with K, the active role in illitization was controlled by Mg. Mineralogical zonation of the K-bentonite is explained by the progressive migration of K from the margins toward the bed center with the associated decrease of K cations in the pore fluids. However, the decrease in K concentration was accompanied by a successive increase in R0 I-S content, but not a progressive decrease in illite layer content in a single I-S phase. The main role of Mg was to redistribute octahedral and tetrahedral Al in the 2:1 layers of the R0 I-S and R1 I-S in such a way that the amount of Al in the tetrahedral sheets increased at the expense of the substitution of Mg for Al in the octahedral sheet of the 2:1 layers in the initial smectite.

These results demonstrate a new insight into mineralogical sequences of intermediate members of smectite illitization. Instead of a statistically homogeneous and continuous reaction associated with the increase of illite layers in I-S and the simultaneous increase of order of the layer stacking sequence, the illitization reaction in the thick K-bentonite consists of the formation of a physical mixture of two I-S having a contrasting content of layer types and their distribution. Factors responsible for the formation of the coexisting R0 I-S and R1 I-S are discussed

Keywords: Illitization; K-bentonite; multispecimen fitting; X-ray diffraction; smectite; cis-vacant; trans-vacant; TGA DTG
Received: 2009-3-28
Accepted: 2009-7-30
Published Online: 2015-4-1
Published in Print: 2009-11-1

© 2015 by Walter de Gruyter Berlin/Boston

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https://doi.org/10.2138/am.2009.3260
Keywords for this article
Illitization; K-bentonite; multispecimen fitting; X-ray diffraction; smectite; cis-vacant; trans-vacant; TGA DTG

Articles in the same Issue

  1. Review Paper. Microbe-clay mineral interactions
  2. Chemical substitutions, paragenetic relations, and physical conditions of formation of högbomite in the Sittampundi layered anorthosite complex, South India
  3. Miguelromeroite, the Mn analogue of sainfeldite, and redefinition of villyaellenite as an ordered intermediate in the sainfeldite-miguelromeroite series
  4. Mechanism and kinetics of a mineral transformation under hydrothermal conditions: Calaverite to metallic gold
  5. A statistical reassessment of the evidence for the racemic distribution of quartz enantiomorphs
  6. On the crystal structure and crystal chemistry of pollucite, (Cs,Na)16Al16Si32O96·nH2O: A natural microporous material of interest in nuclear technology
  7. The effect of fluid inclusion size on determination of homogenization temperature and density of liquid-rich aqueous inclusions
  8. Effect of SiO2, total FeO, Fe3+/Fe2+, and alkali elements in basaltic glasses on mid-infrared
  9. Influence of cation size on the low-temperature heat capacity of alkaline earth metasilicate glasses
  10. The high-pressure–high-temperature behavior of bassanite
  11. Geochemistry of reversible hydratable tephra from the Trans Mexican Volcanic Belt
  12. Physical contradictions and remedies using simple polythermal equations of state
  13. Thermodynamic and crystallographic properties of kornelite [Fe2(SO4)3·~7.75H2O] and paracoquimbite [Fe2(SO4)3·9H2O]
  14. Humidity-induced phase transitions of ferric sulfate minerals studied by in situ and ex situ X-ray diffraction
  15. In situ Raman spectroscopy of MgSiO3 enstatite up to 1550 K
  16. Optical spectroscopic study of tetrahedrally coordinated Co2+ in natural spinel and staurolite at different temperatures and pressures
  17. New insights into smectite illitization: A zoned K-bentonite revisited
  18. The hydrothermal conversion of kaolinite to kalsilite: Influence of time, temperature, and pH
  19. Sideronatrite, Na2Fe(SO4)2(OH)·3H2O: Crystal structure of the orthorhombic polytype and OD character analysis
  20. Anharmonic OH vibrations in brucite: Small pressure-induced redshift in the range 0–22 GPa
  21. Structural properties of biologically controlled hydrozincite: An HRTEM and NMR spectroscopic study
  22. Mechanism of wollastonite carbonation deduced from micro- to nanometer length scale observations
  23. Letter. Crystal structure of argentopyrite, AgFe2S3, and its relationship with cubanite
  24. Letter. Magnetite-free, yellow lizardite serpentinization of olivine websterite, Canyon Mountain complex, N.E. Oregon
  25. Letter. The influence of atomic size and charge of dissolved species on the diffusivity and viscosity of silicate melts
  26. Letter. Si-Al distribution in high-pressure CaAl4Si2O11 phase: A 29Si and 27Al NMR study
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