Iron hydroxides in soils: A review of publications
Tóm tắt
Từ khóa
Tài liệu tham khảo
T. V. Abidueva and T. A. Sokolova, Clay Minerals and the Potassium Status of Steppe Soils of the Western Transbaikal Region (Izd. Sib. Otd. Ross. Akad. Nauk, Novosibirsk, 2005), 100 pp. [in Russian].
T. V. Aristovskaya, Microbiology of Podzolic Soils (Nauka, Leningrad, 1965), 197 pp. [in Russian].
Yu. N. Vodyanitskii, “Iron Hydroxides in Biogenic Neoformations of Forest Soils of the Russian Plain,” Pochvovedenie, No. 12, 1440–1452 (2003) [Eur. Soil Sci. 36 (12), 1286–1297 (2003)].
Yu. N. Vodyanitskii, “Solubility of Iron Oxides of Forest Soils in the Tamm Reagent,” Pochvovedenie, No. 10, 1199–1208 (1998) [Eur. Soil Sci. 31 (10), 1083–1092 (1998)].
Yu. N. Vodyanitskii, Chemistry and Mineralogy of Soil Iron (Pochven. Inst. im. V.V. Dokuchaeva, Moscow, 2003), 238 pp. [in Russian].
Yu. N. Vodyanitskii, E. I. Gagarina, A. D. Gorbovskaya, and A. F. Naumenko, “Forms of Iron Compounds in Soils of Selga Landscape on the Karelian Isthmus,” Pochvovedenie, No. 4, 445–454 (1999) [Eur. Soil Sci. 32 (4), 404–412 (1999)].
Yu. N. Vodyanitskii, A. I. Gorshkov, and A. V. Sivtsov, “Thermodynamically Unstable Iron Hydroxides in Soddy-Podzolic and Brown Forest Soils,” Pochvovedenie, No. 12, 1440–1447 (1996) [Eur. Soil Sci. 29 (12), 1342–1349 (1996)].
Yu. N. Vodyanitskii and V. V. Dobrovol’skii, Iron Minerals and Heavy Metals in Soils (Pochv. Inst. im. V.V. Dokuchaeva, Moscow, 1998), 216 pp. [in Russian].
Yu. N. Vodyanitskii, S. N. Lesovaya, and A. V. Sivtsov, “Iron Hydroxidogenesis in Forest and Steppe Soils of the Russian Plain,” Pochvovedenie, No. 4, 465–475 (2003) [Eur. Soil Sci. 36 (4), 420–429 (2003)].
Yu. N. Vodyanitskii and A. V. Sivtsov, “Formation of Ferrihydrite, Ferroxyhyte, and Vernadite in Soil,” Pochvovedenie, No. 8, 986–999 (2004) [Eur. Soil Sci. 37 (8), 863–875 (2004)].
Supergene Iron Oxides in Geological Processes (Nauka, Moscow, 1975), 206 pp. [in Russian].
A. K. Degtyareva, Author’s Abstract of Cand. Sci. (Biol.) Dissertation (Moscow, 1990), 20 pp. [in Russian].
V. A. Drits, A. I. Gorshkov, B. A. Sakharov, et al., “Ferrihydrite and Its Phase Transformations upon Heating under Oxidative and Reducing Conditions,” Litol. Polezn. Iskopaem., No. 1, 76–84 (1995).
V. S. Savenko, “On the Formation of Iron-Manganic Concretions (A Physicochemical Analysis),” Geokhimiya, No. 8, 1151–1160 (1990).
F. V. Chukhrov, A. I. Gorshkov, and V. A. Drits, Supergene Manganese Oxides (Nauka, Moscow, 1989), 208 pp. [in Russian].
W. A. Adams and J. K. Kassim, “Iron Oxyhydroxides in Soils Developed from Lower Paleozoic Sedimentary Rocks in Mid-Wales and Implications for Some Pedogenetic Processes,” J. Soil Sci. 35, 117–126 (1984).
A. D. Anhar, “Iron Stable Isotopes: Beyond Biosignatures,” Earth Planet. Sci. Lett. 217, 223–236 (2004).
B. L. Beard and C. M. Johnson, “Fe Isotope Variations in the Modern and Ancient Earth and Other Planetary Bodies,” Rev. Mineral. Geochem. 55, 319–357 (2004).
B. L. Beard, C. M. Johnson, L. Cox, et al., “Iron Isotope Biosignatures,” Science 285, 1889–1892 (1999).
S. G. Benner, C. M. Hansel, B. M. Wielinga, and S. Fendorf, “Reductive Dissolution and Biomineralization of Iron Hydroxide under Flow Conditions,” Environ. Sci. Technol. 36, 1705–1711 (2002).
S. L. Brantley, L. Liermann, and T. D. Bullen, “Fractionation of Fe Isotopes by Soil Microbes and Organic Acids,” Geology 29, 535–538 (2001).
S. L. Brantley, L. Liermann, R. L. Guynn, et al., “Fe Isotopic Fractionation during Mineral Dissolution with and Without Bacteria,” Geochim. Cosmochim. Acta 68, 3189–3204 (2004).
L. Carlson and U. Schwertmann, “Natural Occurrence of Feroxyhyte (δ′-FeOOH),” Clays Clay Minerals 28(4), 272–280 (1980).
R. M. Cornell and U. Schwertmann, The iron oxidesstructure, properties, reactions, occurrence and uses, 2nd ed. VCH. Weinheim. 665 p. (2003).
H. A. Crosby, C. M. Johnson, E. E. Roden, and B. L. Beard, “Coupled Fe(II)-Fe(III) Electron and Atom Exchange as a Mechanism for Fe Isotope Fractionation during Dissimilatory Iron Oxide Reduction,” Environ. Sci. Technol. 39, 6698–6704 (2005).
J. Cumplido, V. Barron, and J. Torrent, “Effects of Phosphate on the Formation of Nanophase Lepidocrocite from Fe(II) sulfate,” Clays Clay Miner. 48, 503–510 (2000).
I. Diakonov, I. Khodakovsky, J. Schott, and E. Sergeeva, “Thermodynamic Properties of Iron Oxides and Hydroxides. I. Surface and Bulk Thermodynamic Properties of Goethite (-FeOOH) up to 500 K,” Eur. J. Mineral. 6, 967–983 (1994).
M. H. Ebinger and D. G. Schulze, “The Influence of pH on the Synthesis of Mixed Fe-Mn Oxide Minerals,” Clay Miner. 25, 507–518 (1990).
R. A. Eggleton and R. W. Fitzpatrick, “New Data and a Revised Structural Model for Ferrihydrite,” Clays Clay Miner. 36, 111–124 (1988).
M. S. Fantle and D. J. DePaolo, “Iron Isotope Fractionation during Continental Weathering,” Earth Planet. Sci. Lett. 217, 547–562 (2004).
R. W. Fitzpatrick and U. Schwertmann, “Al-Substituted Goethite, an Indicator of Pedogenic and Other Weathering Environments in South Africa,” Geoderma 27, 335–347 (1982).
R. W. Fitzpatrick, R. M. Taylor, U. Schwertmann, and C. W. Childs, “Occurrence and Properties of Lepidocrocite in Some Soils of New Zealand, South Africa and Australia,” Aust. J. Soil. Res. 23, 543–567 (1985).
N. Galvez, V. Barron, and J. Torrent, “Effect of Phosphate on Crystallization of Hematite, Goethite, and Lepidocrocite from Ferrihydrite,” Clays Clay Miner. 47(3), 304–311 (1999).
A. N. Halliday, D.-C. Lee, J. N. Christensen, et al., “Application of Multiple Collector-ICPMS to Cosmochemistry, Geochemistry, and Paleoceanography,” Geochim. Cosmochim. Acta 62, 919–940 (1998).
M. G. Johnson and M. B. McBride, “Mineralogical and Chemical Characteristics of Adirondack Spodosols: Evidence for Para- and Noncrystalline Minerals,” Soil Sci. Soc. Am. J. 53(2), 482–490 (1989).
C. M. Hansel, S. G. Benner, and S. Fendorf, “Competing Fe(II)-Induced Mineralization Pathways of Ferrihydrite,” Environ. Sci. Technol. 30, 1540–1552 (1996).
C. M. Hansel, S. G. Benner, J. Neiss, et al., “Secondary Mineralization Pathways Induced by Dissmilatory Iron Reduction of Ferrihydrite under Advective Flow,” Geochim. Cosmochim. Acta 67, 2977–2992 (2003).
C. M. Johnson, B. L. Beard, E. E. Roden, et al., “Isotopic Constraints on Biogeochemical Cycling of Fe,” Rev. Mineral. Geochem. 55, 359–408 (2004).
Z. Karim and A. C. D. Hewman, “The Possible Effect of Soluble Silicon on the Lepidocrocite Content of Gley Soils from England and Bangladesh,” J. Soil Sci. 37, 259–266 (1986).
H. Kodama and C. Wang, “Distribution and Characterization of Noncrystalline Inorganic Components in Spodosols and Spodosol-Like Soils,” Soil Sci. Soc. Am. J. 53(2), 526–533 (1989).
G. S. R. Krishnamurti and P. M. Huang, “Formation of Lepidocrocite from Iron (II) Solution: Stabilization by Citrate,” Soil Sci. Soc. Am. J. 57, 861–867 (1993).
W. L. Lindsay, “Solubility and Redox Equilibria of Iron Compounds in Soil,” in Iron in Soils and Clay Minerals (Reidel, Dordrecht, 1988), pp. 99–140.
J. Masedo and R. B. Bryant, “Preferential Microbial Reduction of Hematite over Goethite in a Brazilian Oxisol,” Soil Sci. Am. J. 53, 1114–1118 (1989).
J. Majzlan, C. B. Koch and A. Navrotsky, “Thermodynamic Properties of Feroxyhyte (δ-FeOOH),” Clays Clay Miner. 56, 526–530 (2008).
A. Manceau, V. A. Drits, “Local Structure of Ferrihydrite and Feroxyhite by EXAFS Spectroscopy,” Clay Miner. 28, 165–184 (1993).
C. E. Martinez and M. B. McBride, “Coprecipitates of Cd, Cu, Pb and Zn in Iron Oxides: Solid Phase Transformation and Metal Solubility after Aging and Thermal Treatment,” Clays Clay Miner. 46, 537–545 (1998).
A. Matthews, H. S. Morgan-Bell, S. Emmanuel, et al., “Controls on Iron-Isotope Fractionation in Organic-Rich Sediments (Kimmeridge Clay, Upper Jurassic, Southern England),” Geochim. Cosmochim. Acta 68, 3107–3123 (2004).
H. D. Pedersen, D. Postma, and R. Jakobsen, “Release of Arsenic Associated with the Reduction and Transformation of Iron Oxides,” Geochim. Cosmochim. Acta 70, 4116–4129 (2006).
H. D. Pedersen, D. Postma, R. Jakobsen, and O. Larsen, “Fast Transformation of Iron Oxyhydoxides by Catalytic Action of Fe(II),” Geochim. Cosmochim. Acta 69, 3967–3977 (2005).
G. S. Pokrovski, J. Schott, F. Farges, and J.-L. Hazemann, “Iron (III)-Silica Interactions in Aqueous Solution: Insights from X-Ray Absorption Fine Structure Spectroscopy,” Geochim. Cosmochim. Acta 67, 3559–3573 (2003).
J. D. Russell, “Infrared Spectroscopy of Ferrihydrite: Evidence for the Presence of Structural Hydroxyl Groups,” Clays Clay Miner. 14, 109–114 (1979).
U. Schwertmann, “Occurrence and Formation of Iron Oxides in Various Pedoenviroment,” in Iron in Soil and Clay Minerals (Reidel, Dordrecht, 1988), pp. 267–308.
U. Schwertmann, “Some Properties of Soil and Synthetic Iron Oxides,” in Iron in Soil and Clay Minerals (Reidel, Dordrecht, 1988), pp. 203–250.
U. Schwertmann and R. W. Fitzpatrick, “Occurrence of Lepidocrocite and Its Association with Goethite in Natal Soils,” Soil Sci. Soc. Am. J. 41, 1013–1018 (1977).
U. Schwertmann, H. Stanjek, and H.-H. Becher, “Long-Term in Vitro Transformation of 2-Line Ferrihydrite to Goethite/Hematite at 4, 10, 15 and 25°C,” Clay Miner. 39, 433–438 (2004).
U. Schwertmann and R. M. Taylor, “Iron Oxides,” in Minerals in Soil Environments, J. B. Dixon and S. B. Weed (Eds.), (Madison, Wis., 1989), pp. 379–438.
J. L. Skulan, B. L. Beard, and C. M. Johnson, “Kinetic and Equilibrium Fe Isotope Fractionation between Aqueous Fe(III) and Hematite,” Geochim. Cosmochim. Acta. 66, 2995–3015 (2002).
J. W. Stucki, L. Kangwon, B. A. Goodman, and J. E. Kostka, “Effects of in Situ Biostimulation of Iron Mineral Speciation in a Sub-Surface Soil,” Geochim. Cosmochim. Acta 71, 835–843 (2007).
S.-I. Wada and N. Ueno, “Effect of Monosilicic Acid on Hydrolytic Polymerization of Fe(III) and Structure of Hydrolytic Products,” Soil Sci. Plant. Nutr. 47, 727–735 (2001).
J. G. Wiederhold, S. M. Kraemer, N. Teutsch, et al., “Iron Isotope Fractionation during Proton-Promoted, Ligand-Controlled, and Reductive Dissolution of Goethite,” Environ. Sci. Technol. 40, 3787–3793 (2006).
J. G. Wiederhold, N. Teutsch, R. Kretzschmar, et al., “Iron Isotope Fractionation during Soil Formation — Comparison of Ligand and Redox Controlled Processes,” Geochim. Cosmochim. Acta 68, 11 (2004).