Hostname: page-component-586b7cd67f-2plfb Total loading time: 0 Render date: 2024-11-26T02:57:30.690Z Has data issue: false hasContentIssue false
  • English
  • Français

Role of clays in the diagenetic history of nitrogen and boron in the Carboniferous of Donbas (Ukraine)

Published online by Cambridge University Press:  09 July 2018

J. Środoń  and
M. Paszkowski
J. Środoń*
Affiliation:
Institute of Geological Sciences, Polish Academy of Sciences, Research Centre in Kraków, Senacka St. 1, PL-31002 Kraków, Poland
M. Paszkowski
Affiliation:
Institute of Geological Sciences, Polish Academy of Sciences, Research Centre in Kraków, Senacka St. 1, PL-31002 Kraków, Poland
*
*E-mail: [email protected]
Get access Rights & Permissions [Opens in a new window]

Abstract

The evolution of the nitrogen and boron content of shales during diagenesis and anchimetamorphism was studied in the Carboniferous rocks of Donbas by means of the bulk rock chemical analysis and the XRD quantification of mineral composition, aided by CEC and EGME sorption measurements. The contributions of the organic-bound N and B were taken into account, based on the literature data (B) and on the relationship established in the course of this study (N). 28–98% of the total N and 80–100% of the total B are contained in the mineral fraction of the investigated shales.

The mineral nitrogen is located mostly in illite and accounts for 3 to 64% of the sites available for its fixation in 1Md illite. The fixation of N by illite seems to diminish in the course of diagenesis, but additional fixation occurs in newly formed 2M1 illite during the anchimetamorphic stage. The volume of N contained in illite in most samples greatly surpasses the N available locally from the organic matter contained in shale. Modelling indicates that the measured level of N for K substitution in illite corresponds to the capture in 30 vol.% of shale of all N released in a basin containing 5 vol.% of coal.

Boron is held predominantly by the 1Md fraction (illite+smectite). During diagenesis boron is redistributed into the 1Md illite, and during anchimetamorphism it is released from the 1Md illite and incorporated into new 2M1 illite. No indication of the net enrichment of pore water in B due to the clay alteration process was found.

Keywords

ammoniumanchimetamorphismborondiagenesisDonbasDonets BasinUkraineilliteillite-smectitenitrogenpore watershale
Type
Research Article
Information
Clay Minerals , Volume 46 , Issue 4 , December 2011 , pp. 561 - 582
Copyright
Copyright © The Mineralogical Society of Great Britain and Ireland 2011

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Ader, M., Boudou, J.-P. Javoy, M. Goffe, B. & Daniels, E. (1998) Isotope study on organic nitrogen of Westphalian anthracites from the Western Middle field of Pennsylvania (U.S.A.) and from the Bramsche Massif (Germany). Organic Geochemistry, 29, 315323.Google Scholar
Aloisi, G., Drews, M., Wallmann, K. & Bohrmann, G. (2004) Fluid expulsion from the Dvurechenskii mud volcano (Black Sea). Part I. Fluid sources and relevance to Li, B, Sr, I and dissolved inorganic nitrogen cycles. Earth and Planetary Science Letters, 225, 347363.Google Scholar
Alsaab, D., Elie, M., Izart, A., Sachsenhofer, R.F., Privalov, V.A., Suarez-Ruiz, I., Martinez, L. & Panova, E.A. (2008) Distribution of thermogenic methane in Carboniferous coal seams of the Donets Basin (Ukraine): Applications to exploitation of methane and forecast of mining hazards. International Journal of Coal Geology, 74, 154162.Google Scholar
Bardon, C., Bieber, M.T., Cuiec, L., Jacquin, C., Courbot, A., Deneuville, G., Simon, J.M., Voirin, J.M., Espy, M., Nectoux, A. & Pellerin, A. (1983) Recommandations pour la détermination expérimentale de la capacité d'échange de cations des milieux argileux. Revue de l' Institut Français du Pétrole, 38,621-626.Google Scholar
Bottomley, D.J. & Clark, I.D. (2004) Potassium and boron co-depletion in Canadian Shield brines: evidence for diagenetic interactions between marine brines and basin sediments. Chemical Geology, 203, 225236.Google Scholar
Boudou, J.-P., Schimmelmann, A., Ader, M., Mastalerz, M., Sebilo, M. & Gengembre, L. (2008) Organic nitrogen chemistry during low-grade metamorphism. Geochimica et Cosmochimica Acta, 72, 11991221.Google Scholar
Cooper, I.E. & Abedin, K.Z. (1981) The relationship between fixed ammonium-nitrogen and potassium in clays from a deep well on the Texas Gulf Coast. Texas Journal of Science, 34, 103111.Google Scholar
Daniels, E.J. & Altaner, S.P. (1990) Clay mineral authigenesis in coal and shale from the Anthracite region, Pennsylvania. American Mineralogist, 75, 825839.Google Scholar
Ellis, D.V. & Singer, J.M. (2007) P. 353 in: Well Logging for Earth Scientists. Springer, Dordrecht, The Netherlands.Google Scholar
Eskenazy, G., Delibaltova, D. & Mincheva, E. (1994) Geochemistry of boron in Bulgarian coals. International Journal of Coal Geology, 25, 93 —110.CrossRefGoogle Scholar
Francu, J., Müller, P., Šucha, V. & Zatkaliková, V. (1990) Organic matter and clay minerals as indicators of thermal history in the Transcarpathian Depression (East Slovakian Neogene Basin) and the Vienna Basin. Geologica Carpathica, 41, 535546.Google Scholar
Frederickson, A.F. & Reynolds, R.C. Jr. (1960) Geochemical method for determining paleosalinity. Clays and Clay Minerals, Proceedings of the Eighth National Conference, 202.Google Scholar
Goldschmidt, V.M. & Peters, C. (1932) Geochemie des Bors: I, II. Nachrichten Der Akademie der Wissenschaften in Göttingen, Mathematische-Physikalische Klasse 111, 402-407, 528545.Google Scholar
Goodarzi, F. & Swaine, D.J. (1994) The influence of geological factors on the concentration of boron in Australian and Canadian coals. Chemical Geology, 118, 301318.Google Scholar
Grad, M., Gryn, D., Guterch, A., Janik, T., Keller, R., Lang, R., Lyngsie, S.B., Omelchenko, V., Starostenko, V.I., Stephenson, R.A., Stovba, S.M., Thybo, H. & Tolkunov, A. (2003) “DOBREfraction'99” - velocity model of the crust and upper mantle beneath the Donbas Foldbelt (East Ukraine. Tectonophysics, 371, 81110.Google Scholar
Hower, J.C., Ruppert, L.F. & Williams, D.A. (2002) Controls of boron and germanium distribution in the low-sulfur Amos coal bed, Western Kentucky coalfield, USA. International Journal of Coal Geology, 53, 2742.Google Scholar
Jackson, M.L. (1975) Soil Chemical Analysis — Advanced Course. Published by the author, Madison, Wisconsin, USA.Google Scholar
Karpova, G.V. (1969) Clay mineral post-sedimentary ranks in terrigenous rocks. Sedimentology, 13, 520.Google Scholar
Krooss, B.M., Jurisch, A. & Plessen, B. (2006) Investigation of the fate of nitrogen in Palaeozoic shales of the Central European Basin. Journal of Geochemical Exploration, 89, 191194.Google Scholar
Lindgreen, H., Drits, V.A., Sakharov, B.A., Salyn, A.L., Wrang, P. & Dainyak, L.G. (2000) Illite-smectite structural changes during metamorphism in black Cambrian Alum shales from the Baltic area. American Mineralogist, 85, 12231238.Google Scholar
Mingram, B., Hoth, P., Luders, V. & Harlov, D. (2005) The significance of fixed ammonium in Palaeozoic sediments for the generation of nitrogen-rich natural gases in the North German Basin. International Journal of Earth Sciences, 94, 10101022.Google Scholar
Moore, D.M. & Reynolds, R.C. (1997) X-Ray Diffraction and the Identification and Analysis of Clay Minerals. Oxford University Press, Oxford-New York, 378 pp.Google Scholar
Mystkowski, K., Środoń, J. & McCarty, D.K. (2002) Application of evolutionary programming to automatic XRD quantitative analysis of clay-bearing rocks. The Clay Minerals Society 39th Annual Meeting, Boulder, Colorado, Abstracts with Programs. Google Scholar
Omotoso, O., McCarty, D.K., Hillier, S. & Kleeberg, R. (2006) Some successful approaches to quantitative mineral analysis as revealed by the 3rd Reynolds Cup contest. Clays and Clay Minerals, 54, 748760.Google Scholar
Orsini, L. & Remy, J.-C. (1976) Utilisation du chlorure de cobaltihexammine pour la determination simultanee de la capacite d'echange et des bases echangeables des sols. Science du Sol, 4, 269275.Google Scholar
Reynolds, R.C. Jr. (1965) Geochemical behavior of boron during the metamorphism of carbonate rocks. Geochimica et Cosmochimica Ada, 29, 11011114.Google Scholar
Sachsenhofer, R.F., Privalov, V.A. & Panova, E.A. (2011) Basin evolution and coal geology of the Donets Basin (Ukraine, Russia): An overview. International Journal of Coal Geology. doi:10.1016/j.coal.2011.05.002Google Scholar
Sivan, T.P. (1972) Statistical substantiation of the significance of boron dissolved in underground waters of the Crimea for oil and gas exploration. Soviet Geology, 10, 148151.Google Scholar
Smishko, R.M. (2002) Structural peculiarities of the Donets'k basin in connection with gas bearing. Visnik Lvivskogo Universitetu, Ser. Geol., 16, 6369.Google Scholar
Środoń, J. (2007) Illitization of smectite and history of sedimentary basins. Proceedings of the 11* EUROCLAY Conference, Aveiro, Portugal, 7482.Google Scholar
Środoń, J. (2009) Quantification of illite and smectite and their layer charges in sandstones and shales from shallow burial depth. Clay Minerals, 44, 421434.Google Scholar
Środoń, J. (2010) Evolution of boron and nitrogen content during illitization of bentonites. Clays and Clay Minerals, 58, 743756.Google Scholar
Środoń, J. & McCarty, D.K. (2008) Surface area and layer charge of smectite from CEC and EGME/H2O retention measurements. Clays and Clay Minerals, 56, 142161.Google Scholar
Środoń, J., Drits, V.A., McCarty, D.K., Hsieh, J.C.C. & Eberl, D.D. (2001) Quantitative XRD analysis of clay-rich rocks from random preparations. Clays and Clay Minerals, 49, 514528.Google Scholar
Środoń, J., Kotarba, M., Biroii, A., Such, P., Clauer, N. & Wojtowicz, A. (2006) Diagenetic history of the Podhale-Orava basin and the underlying Tatra sedimentary structural units (Western Carpathians): evidence from XRD and K-Ar of illite-smectite. Clay Minerals, 41, 747770.Google Scholar
Środoń, J., Zeelmaekers, E. & Derkowski, A. (2009) Charge of component layers of illite-smectite in bentonites and the nature of end-member illite. Clays and Clay Minerals, 57, 650672.Google Scholar
Stevenson, F.J. (1962) Chemical state of the nitrogen in rocks. Geochimica et Cosmochimica Ada, 26, 797811.CrossRefGoogle Scholar
Šucha, V., Kraus, I., Gerthofferova, H., Petes, J. & Serekova, M. (1993) Smectite to illite conversion in bentonites and shales of the East Slovak Basin. Clay Minerals, 28, 243253.Google Scholar
Šucha, V., Kraus, I. & Madejova, J. (1994) Ammonum illite from anchimetamorphic shales associated with anthracite in the Zemplinicum of the Western Carpathians. Clay Minerals, 29, 369377.Google Scholar
Šucha, V., Elsass, F., Eberl, D.D., Kuchta, L., Madejova, J., Gates, W.P. & Komadel, P. (1998) Hydrothermal synthesis of ammonium illite. American Mineralogist, 83, 5867.Google Scholar
Thamdrup, B. & Dalsgaard, T. (2008). Nitrogen cycling in sediments. Pp. 527568 in: Microbial Ecology of the Oceans (Kirchman, D.L., editor). John Wiley & Sons, Inc. Google Scholar
Vishnevskaya, V.S. & Sedaeva, K.M. (2000) Specific features of Early-Middle Carboniferous sedimentation in the southern part of the East European Platform. Lithology and Mineral Resources, 35, 455465.Google Scholar
Wiewiora, A. & Wilamowski, A. (1996) The relationship between composition and b for chlorite. Geologica Carpathica - Series Clays, 5, 7987.Google Scholar
Williams, L.B. & Ferrell, R.E. Jr., (1991) Ammonium substitution in illite during maturation of organic matter. Clays and Clay Minerals, 39, 400408.Google Scholar
Williams, L.B., Hervig, R.L., Holloway, J.R. & Hutcheon, I. (2001a) Boron isotope geochemistry during diagenesis. Part I. Experimental determination of fractionation during illitization of smectite. Geochimica et Cosmochimica Ada, 65, 17691782.Google Scholar
Williams, L.B., Hervig, R.L. & Hutcheon, I. (2001b) Boron isotope geochemistry during diagenesis. Part II. Applications to organic-rich sediments. Geochimica et Cosmochimica Ada, 65, 17831794.Google Scholar
Zorski, T., Ossowski, A., Środoń, J. & Kawiak, T. (2011) Evaluation of mineral composition and petrophysieal parameters by the integration of core analysis data and wireline well log data: the Carpathian Foredeep case study. Clay Minerals, 46, 2545.Google Scholar
Zuber, A. & Chowaniec, J. (2009) Diagenetic and other highly mineralized waters in the Polish Carpathians. Applied Geochemistry, 24, 18891900.Google Scholar