Инд. авторы:	Leonova G.A., Maltsev A.E., Preis Y.I., Miroshnichenko L.V.
Заглавие:	Biogeochemistry of holocene peatlands in the baraba forest-steppe (southern West Siberia)
Библ. ссылка:	Leonova G.A., Maltsev A.E., Preis Y.I., Miroshnichenko L.V. Biogeochemistry of holocene peatlands in the baraba forest-steppe (southern West Siberia) // Applied Geochemistry. - 2021. - Vol.124. - Art.104811. - ISSN 0883-2927.
Внешние системы:	DOI: 10.1016/j.apgeochem.2020.104811; РИНЦ: 45149438; WoS: 000612399200004;
Реферат:	eng: Postdepositional diagenetic processes and behavior of biogenic and other elements in Holocene peatlands have been studied in Ubinskoe and Sherstobitovo bogs of the Baraba forest-steppe zone. Peat contains relatively high concentrations of Fe, Mn, Pb, Hg, Sb, Cd, Cu, and Zn in the upper part of the two sections and S, N, Ca, and Sr in the middle. Microbially mediated processes in peat affect the behavior of pH and Eh and cycles of biogenic elements. Depth-dependent distribution patterns of microorganisms in the two bogs record active cycles of carbon and nitrogen but limited sulfur exchange. Bog waters have Ca-group bicarbonate major-ion chemistry and high concentrations of Al, Fe, Cu, and Zn, due to low pH. High contents of NH4(+), NO3-, and C-org and chemical oxygen demand (COD) in the bog waters are implicit indicators of rapid biochemical decomposition and oxidation of organic matter. The low pH of the water and an oxic environment in peat were favorable for the formation of goethite and hydrogoethite in upper peat layers. The formation of hematite and andhydride may be related with past wild fires. Early diagenetic processes lead to precipitation of authigenic minerals, especially, pyrite or less often siderite, calcite, and kaolinite. Reduced conditions maintained the formation of metallic Ni and intermetallic Ni-Cr nanometer particles, as well as precipitation of amorphous silica upon dissolution of aluminosilicate minerals in upper peat intervals.Y
Ключевые слова:	DEPOSIT; ECOSYSTEMS; GEOCHEMISTRY; MASS-BALANCE; MAJOR ELEMENTS; TRACE-ELEMENTS; CHEMICAL-ELEMENTS; PEAT BOG PROFILES; Microorganisms; Organic matter; Geochemistry; Holocene; Diagenesis; Bogs; JURA MOUNTAINS; DEPTH;
Издано:	2021
Физ. характеристика:	104811
Цитирование:	1. Anderson, H., Hepburn, A., Variation of humic substances within peat profile. Fuchsman, C.H., (eds.) Peat and Water, 1986, Academic Press, New York, 177–194. 2. Arkhipov, V.S., Bernatonis, V.K., Distribution of calcium and iron in the vertical profile of peat deposits in the taiga zone of West Siberia. Bull. Tomsk. Polytechnical University 323:1 (2013), 173–178. 3. Bakhtin, A.I., Kolchugin, A.N., Eskin, A.A., Geochemistry of deposition and stability of calcium sulfates in nature. Transactions, Kazan University. Natural Science Series 154:4 (2012), 55–60 ([in Russian]). 4. Bobrov, V.A., Preis, YuI., Budashkina, V.V., Assessment of airborne mineral fluxes bedrockd on trace-element compositions of peat in the Bakchar-1 high bog (southern taiga of West Siberia). Problemy Biogeokhimii i Geokhimicheskoi Ekologii 22:1 (2013), 20–29. 5. Bobrov, V.A., Maltsev, A.E., Leonova, G.A., Melenevsky, V.N., Klimin, M.A., Shavekin, A.S., Vosel, YuS., Miroshnichenko, L.V., Bobrov, S.V., Geochemistry of early diagenesis of peat in Vydrino raised bog (southern Baikal region). Lithology of Sedimentary Complexes in Eurasia and Offshore Areas, Proc. IX All-Russian Lithological Meeting (With International Contributions), 2019, Kazan University Press, Kazan, 50–51. 6. Boquete, M.T., Fernández, J.A., Aboal, J.R., Carballeira, A., Are terrestrial mosses good biomonitors of atmospheric deposition of Mn?. Atmos. Environ. 45 (2011), 2704–2710. 7. Borgmark, A., Holocene climate variability and periodicities in south-central Sweden, as interpreted from peat humification analysis. Holocene 15:3 (2005), 387–395. 8. Document, Regulatory, Working document RD 52 24 493 2006. Mass Concentration of Bicarbonates and Alkalinity of Terrestrial Surface Waters and Treated Waste Waters, 2006, Titration Methods, Rostov on Don. 9. Efremova, T.T., Efremov, S.P., Kutsenogy, K.P., Onuchin, A.A., Peresedov, V.F., Biogeochemistry of Fe, Mn, Cr, Ni, Co, Ti, V, Mo, Ta, W, and U in a low moor peat deposit of the Ob'-Tom' interfluve. Eurasian Soil Sci. 36:5 (2003), 501–510. 10. Fadeeva, V.P., Tikhova, V.D., Nikulicheva, O.N., Elemental analysis of organic compounds with the use of automated CHNS analyzers. J. Anal. Chem. 63:11 (2008), 1094–1106. 11. Fischer, W.R., Schwertmann, U., The formation of hematite from amorphous iron (III) hydroxide. Clay Clay Miner. 23 (1975), 33–37. 12. Garrels, R.M., Christ, C.L., Solutions, Minerals, and Equilibria. 1965, Harper & Row, New York. 13. Gavshin, V.M., Bobrov, V.A., Sukhorukov, F.V., Budashkina, V.V., Melgunov, M.S., Fractionation of chemical elements in the atmosphere of Western Siberia: evidence from an ombrotrophic peat bog. Dokl. Earth Sci. 397:5 (2004), 668–671. 14. González-Pérez, J.A., Jiménez-Morillo, N.T., San Emeterio, L.M., Almendros, G., González-Vila, F.J., Organic geochemistry of Ribetehilo peat bog. Proc. 1st Iberian Meeting in Separation Sciences & Mass Spectrometry, 2019, Sociedad Española de Cromatografía y Técnicas Afines, Santiago de Compostela, 176–177. 15. Gorham, E., Janssens, J.A., The distribution and accumulation of chemical elements in five peat cores from the mid-continent to the eastern coast of North America. Wetlands 25:2 (2005), 259–278. 16. Helmer, E.H., Urban, N.R., Eisenreich, S.J., Aluminum geochemistry in bog waters. Biogeochemistry 9:3 (1990), 247–276. 17. Kempter, H., Krachlera, M., Shotyk, W., Zaccone, C., Major and trace elements in Sphagnum moss from four southern German bogs, and comparison with available moss monitoring data. Ecol. Indicat. 78 (2017), 19–25. 18. Khakhinov, V.V., Namsaraev, B.B., Dorzhieva, G.S.-S., Buryukhaev, S.P., Hydrochemical and microbiological characteristics of bog ecosystems on the isthmus of Svyatoi nos Peninsula (Lake Baikal). Geografiya i Prirodnye Resursy 33:4 (2012), 298–303. 19. Khazin, L.B., Khazina, I.V., Krivonogov, S.K., Kuzmin, YaV., Prokopenko, A.A., Yi, S., Burr, G.S., Holocene climate changes in southern West Siberia bedrockd on ostracod analysis. Russ. Geol. Geophys. 57:4 (2016), 574–585. 20. Khotinsky, N.A., The position of forest/steppe boundary in middle and late Holocene West Siberia. Soveskoye Pochvovedenie 6 (1970), 40–47. 21. Lambers, H., Chapin, F.S., Pons, T.L., Plant Physiological Ecology. second ed., 2008, Springer. 22. Leonova, G.A., Bobrov, V.A., Maltsev, A.E., Holocene biogeochemistry of a peat bog in the Dulikha massif (southern Baikal region). West Siberian Peatlands and the Carbon Cycle: Past and Present, Proc. Fifth International Field Symposium, 2017, TSU, Tomsk, 152–154. 23. Leonova, G.A., Maltsev, A.E., Badmaev, J.O., Shavekin, A.S., Rubanov, M.V., Preis, YuI., Geoenvironment assessment of anthropogenic heavy metal pollution of bog ecosystems in the West Siberian forest-steppe zone. Ekologiya Promyshlennogo Proizvodstva 2:102 (2018), 64–73. 24. Li, Y.-h., Distribution patterns of the elements in the ocean: a synthesis. Geochem. Cosmochim. Acta 55 (1991), 3223–3240. 25. Liss, O.L., Abramova, L.I., Avetov, N.A., Berezina, N.A., Inisheva, L.I., Kurnishkova, T.V., Sluka, Z.A., Tolpysheva, T.Yu, Shvedchikova, N.K., Wetland Systems of West Siberia and Their Environmental Significance. 2001 Grif & Co Tula. 26. Lukashev, K.I., Kovalev, V.A., Zhukhovitskaya, A.L., Khomich, A.A., Generalova, V.A., Geochemistry of Limnic and Peatland Lithogenesis. 1971, Nauka i Tekhnika, Minsk. 27. Malawskaand, M., Wilkomirski, B., Geochemistry and geochemical differentiation on major elements in selected peat bog profiles (south-east of Poland). Soil Sci. Plant Nutr. 50:6 (2004), 925–930. 28. Namsaraev, B.B., Zemskaya, T.I., Microbiological Processes of Carbon Cycle in the Bottom Sediments of Lake Baikal. 2000, GEO, Novosibirsk. 29. Naumov, A.V., Kosykh, N.P., Parshina, E.K., Artymuk, S.Yu, Raised bogs of the forest-steppe zone, their state and monitoring. Contemporary Problems of Ecology 2:6 (2009), 671–677. 30. Norms, Conservation, Regulations, Working Document PND F 14 1 2 3 96 97. 2004, Methods for Argentometric Measurements of Chloride Concentrations in Samples of Natural and Treated Waste Waters, Moscow 2004. 31. Norms, Conservation, Regulations, Working Document PND F 14.1 2 159. 2005, Methods for Turbidimetric Measurements of Sulfate-Ion Concentrations in Samples of Natural and Treated Waste Waters, Moscow 2000. 32. Norton, S.A., Evans, G.C., Kahl, J.S., Comparison of Hg and Pb fluxes to hummocks and hollows of ombrotrophic Big Heath Bog and to nearby Sargent Mt. Pond, Maine, USA. Water, Air, Soil Pollut. 100 (1997), 271–286. 33. Orlova, L.A., Volkova, V.S., Holocene Stratigraphy and Radiocarbon Chronology of the Baraba Steppe. 1990, Nauka, Novosibirsk. 34. Preis, YuI., Detailed reconstruction of the functional state of the swamp as a response to changes in the continental climate of the Holocene (middle taiga of Western Siberia). Bulletin of the Tomsk Polytechnic University 326:2 (2015), 90–102. 35. Rozhdestvina, V.I., Sorokin, A.P., First finds of native palladium, platinum, gold, and silver in brown coals of the Erkovets field (upper Amur region). Russian Journal of Pacific Geology 4:6 (2010), 483–494. 36. Savchenko, N.V., Plainland Lakes in Southern West Siberia. 1997, Institute of Soil Science and Agrochemistry, Novosibirsk. 37. Savichev, O.G., Distribution of inorganic pollutants over the depth of upper peat deposit. Contemporary Problems of Ecology 8:1 (2015), 118–124. 38. Savichev, O.G., Inisheva, L.I., Biochemical activity of the peat soil of a river marsh ecosystem. Contemporary Problems of Ecology 6:1 (2008), 667–673. 39. Savichev, O.G., Shmakov, A.V., Vertical zoning and seasonal water chemistry changes in the Timiryazevsky swamp (Tomsk, Western Siberia). Bull. Tomsk Polytechnical University 320:1 (2012), 156–172. 40. Savichev, O.G., Nalivaiko, N.G., Rudmin, M.A., Mazurov, A.K., Microbiological conditions for depth-dependent element distribution in peat of the eastern Vasyugan swamp ecosystems (West Siberia). Bull. Tomsk Polytechnical University 330:9 (2019), 184–194. 41. Savichev, O.G., Soldatova, E.A., Rudmin, M.A., Mazurov, A.K., Geochemical barriers in oligotrophic peat bog (Western Siberia). Appl. Geochem., 113, 2020, 10.1016/j.apgeochem.2019.104519. 42. Shotyk, W., Natural and anthropogenic enrichments of As, Cu, Pb, Sb, and Zn in rainwater-dominated versus groundwater-dominated peat bog profiles, Jura Mountains, Switzerland. Water, Air. Soil Pollut 84 (1996), 1–31. 43. Shotyk, W., Atmospheric deposition and mass balance of major and trace elements in two oceanic peat bog profiles, northern Scotland and Shetland Islands. Chem. Ceol. 138 (1997), 55–72. 44. Shotyk, W., Cheburkin, A.K., Appleby, P.G., Fankhauser, A., Kramers, J.D., Two thousand years of atmospheric arsenic, antimony and lead deposition in an ombrotrophic bog profile, Jura Mountains, Switzerland. Earth Planet Sci. Lett. 145 (1966), 1–7. 45. Shotyk, W., Weiss, D., Kramers, J.D., Frei, R., Cheburkin, A.K., Gloor, M., Reese, S., Geochemistry of the peat bog at Etang de la Gruère, Jura Mountains, Switzerland, and its record of atmospheric Pb and lithogenic trace metals (Sc, Ti, Y, Zr, and REE) since 12,370 14C yr BP. Geochem. Cosmochim. Acta 65:14 (2001), 2337–2360. 46. Shvartsev, S.L., Zdvizhkov, M.A., Serebrennikova, O.V., Savichev, O.G., Naimushina, O.S., Geochemistry of wetland waters from the lower Tom basin, southern Tomsk oblast. Geochem. Int. 50:4 (2012), 367–380. 47. Simonova, V.I., Atomic Absorption Methods for Determination of Elements in Rocks and Minerals. 1986, Nauka, Novosibirsk. 48. Stanton, M.R., Yager, D.B., Fey, D.L., Wright, W.G., Formation and geochemical significance of iron bog deposits. Church, S.E., Guerard, P., Finger, S.E., (eds.) Formation and Geochemical Significance of Iron Bog Deposits, vol. 1651, 2007, U.S. Geological Survey Professional Paper, Colorado, 689–720. 49. State Standard, Working Document GOST R 57162-2016. Water. Determination of Element Content by Graphite Furnace Atomic Absorption Spectrometry. 2016, Standardinform, Moscow. 50. Steinmann, P., Shotyk, W., Geochemistry, mineralogy, and geochemical mass balance on major elements in two peat bog profiles (Jura Mountains, Switzerland). Chem. Geol. 138 (1997), 25–53. 51. Stepanova, V.A., Volkova, I.I., Genesis features of the Nikolaevka ryam in the forest-steppe of western Siberia. Tomsk State University, Journal of Biology 40 (2017), 202–223. 52. Stepanova, V.A., Pokrovsky, O.S., Viers, J., Mironycheva-Tokareva, N.P., Kosykh, N.P., Vishnyakova, E.K., Elemental composition of peat profiles in western Siberia: effect of the micro-landscape, latitude position and permafrost coverage. Appl. Geochem. 53 (2015), 53–70. 53. Veretennikova, E.E., Content and distribution of chemical elements in peats of the southern-taiga subzone of West Siberia. Geografiya i Prirodnye Resursy 2 (2013), 89–95. 54. Volkov, I.I., Sulfur Geochemistry in Ocean Sediments. 1984, Nauka, Moscow. 55. Wilkomirski, B., Malawskaand, M., Characteristics of humic substances in peat of selected peatlands from north-eastern Poland. Soil Sci. Plant Nutr. 50:6 (2004), 931–934. 56. Yudovich, Y.E., Ketris, M.P., Geochemical Tracers of Lithogenesis (Lithological Geochemistry). 2011, Geoprint, Syktyvkar.