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Applied Soil Chemistry. Группа авторовЧитать онлайн книгу.

Applied Soil Chemistry - Группа авторов


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sequence of clay-size minerals in soils and sediments. I. Fundamental generalizations. J. Phys. Chem., 52, 7, 1237–1260, 1948.

      38. Jackson, M.L., Tyler, B., Willis, A.L., Bourbeau, G.A., Pennington, R.P., Weathering sequence of clay-size minerals in soils and sediments: I. Fundamental generalization. J. Phys. Colloid Chem., 52, 1237–1260, 1948.

      39. Jackson, M.L., Hseung, Y., Corey, R.B., Evans, E.J., Vanden Heuvel, R.C., Weathering Sequence of Clay-size Minerals in Soils and Sediments: II. Chemical Weathering of Layer Silicates 1. Soil Sci. Soc. Am. J., 16, 1, 3–6, 1952.

      40. Tamura, T., Jackson, M.L., Sherman, G.D., Mineral Content of Low Humic, Humic and Hydrol Humic Latosols of Hawaii 1. Soil Sci. Soc. Am. J., 17, 4, 343–346, 1953.

      41. Jackson, M.L. and Donald Sherman, G., Chemical weathering of minerals in soils, in: Advances in agronomy, vol. 5, pp. 219–318, Academic Press, Cambridge, Massachusetts, 1953.

      42. Jackson, M.L., Wm Levelt, T.H., Syers, J.K., Rex, R.W., Clayton, R.N., Sherman, G.D., Uehara, G., Geomorphological Relationships of Tropospherically Derived Quartz in the Soils of the Hawaiian Islands 1. Soil Sci. Soc. Am. J., 35, 4, 515–525, 1971.

      43. Haseman, J.F. and Marshall, C.E., The use of heavy minerals in studies of the origin and development of soils, University of Missouri, College of Agriculture, Agricultural Experiment Station, Missouri, 1945.

      44. Marshall, C.E. and Haseman, J.F., The quantitative evaluation of soil formation and development by heavy mineral studies: a Grundy silt loam profile. Soil Sci. Soc. Am. J., 7, C, 448–453, 1943.

      45. Haseman, J.F. and Marshall, C.E., The Use of Heavy Minerals in Studies of the Origin and Development of Soils. Missouri Agricultural Experimental Station. Res. Bull., 387, 387, 1945.

      46. Carroll, D. and Woof, M., Laterite developed on basalt at Inverell, New South Wales. Soil Sci., 72, 2, 87–100, 1951.

      47. Carroll, D., Description of a Montalto soil in Maryland. Soil Sci., 75, 2, 87–102, 1953.

      48. Carroll, D. and Jones, N.K., Laterite developed on acid rocks in southwestern Australia. Soil Sci., 64, 1, 1–16, 1947.

      49. Tyler, S.A. and Marsden, R.W., The nature of leucoxene. J. Sediment. Res., 8, 2, 55–58, 1938.

      50. Bailey, S.W. and Cameron, E.N., Is leucoxene always finely crystalline rutile?; reply. Econ. Geol., 52, 6, 716–720, 1957.

      51. Allen, V.T., Is leucoxene always finely crystalline rutile?; discussion. Econ. Geol., 51, 8, 830, 1956.

      52. Pettijohn, F.J., Persistence of heavy minerals and geologic age. J. Geol., 49, 6, 610–625, 1941.

      53. Jackson, M.L., Clay transformations in soil genesis during the Quaternary. Soil Sci., 99, 1, 15–22, 1965.

      54. Stephens, C.G., Comparative morphology and genetic relationships of certain Australian, North American and European soils. J. Soil Sci., 1, 123–1495, 1950.

      55. Hallsworth, E.G. and Costin, A.B., Soil classification. J. Aust. Inst. Agric. Sci., 16, 84–895, 1950.

      56. Nagelschmidt, G., Desai, A.D., Muir, A., The minerals in the clay fractions of a black cotton soil and a red earth from Hyderabad, Deccan State, India. J. Agric. Sci., 30, 4, 639–653, 1940.

      57. Prescott, J.A., A climatic index for the leaching factor in soil formation. J. Soil Sci., 1, 1, 9–19, 1950.

      58. Hosking, J.S., The soil clay mineralogy of some Australian soils developed on granitic and basaltic parent material. J. Counc. Sci. Ind. Res., Australia, 13, 206–2165, 1940.

      59. Kelley, W.P., Dore, W.H., Woodford, A.O., Brown, S.M., The colloidal constituents of California soils. Soil Sci., 48, 3, 201–256, 1939.

      60. Williams, J.E., Chemical weathering at low temperatures. Geogr. Rev., 39, 1, 129–135, 1949.

      61. McCabe, L.H., Nivation and corrie erosion in West Spitsbergen. Geog. J., 94, 6, 447–465, 1939.

      62. Ekblaw, W.E., The importance of nivation as an erosive factor, and of soil flow as a transporting agency, in northern Greenland. Proc. Natl. Acad. Sci. U.S.A., 4, 9, 288, 1918.

      63. Fieldes, M., Chemical weathering of silicates in soil formation. New Zealand J. Sci. Technol., B, 36, 140–154, 1954.

      64. Fieldes, M. and Williamson, K., II, Clay mineralogy of New Zealand soils; part I, Electron micrography. New Zealand J. Sci. Technol., 37, 314–3355, 1955.

      65. Frederickson, A.F., Mechanism of weathering. Geol. Soc. Am. Bull., 62, 3, 221–232, 1951.

      66. Brown, I.C., Rice, T.D., Byers, H.G., A study of claypan soils. No. 1488-2016-124425, United States Department of Agriculture, Washington, D.C. 1933.

      67. Larson, W.E., Allaway, W.H., Rhoades, H.F., Characteristics of the Clay Fraction of Various Horizons of Scott Silt Loam and Pawnee Silt Loam 1. Soil Sci. Soc. Am. J., 11, C, 443–447, 1947.

      68. Byers, H.G., Alexander, L.T., Holmes, R.S., The composition and constitution of the colloids of certain of the great groups of soils, No. 484. US Dept. of Agriculture, United States, 1935.

      69. Simonson, R.W., Concept of soil, in: Advances in agronomy, vol. 20, pp. 1–47, Academic Press, USA, 1968.

      70. Bartelli, L.J., Soil Taxonomy: Its evolution, status, and future, in: Soil taxonomy—Achievements and challenges, pp. 7–13, 1984.

      71. Richter, D.D. and Babbar, L., II, Soil diversity in the tropics, in: Advances in ecological research, vol. 21, pp. 315–389, Academic Press, Cambridge, Massachusetts, 1991.

      72. Evans, E.J. and Jackson, M.L., Chemical determination of sorbed water and structural hydroxyl in colloidal minerals of soils and sediments. Soil Sci. Soc. Am. J., 16, 4, 364–368, 1952.

      73. Retzer, J.L., Soil Development in the Rocky Mountains. Soil Sci. Soc. Am. J., 13, C, 446–448, 1949.

      74. Snider, H.J., The solubility of phosphorus in soils from some Illinois experiment fields. Soil Sci., 38, 6, 471–476, 1934.

      75. Nutting, P.G., Some standard thermal dehydration curves of minerals, US Government Printing Office, United States, 1943.

      76. Nutting, P.G., The action of some aqueous solutions on clays of the montmorillonite group, No. 197. US Government Printing Office, United States, 1943.

      77. Lange, M.A., Lambert, P., Ahrens, T.J., Shock effects on hydrous minerals and implications for carbonaceous meteorites. Geochim. Cosmochim. Acta, 49, 8, 1715–1726, 1985.

      78. Grim, R.E. and Rowland, R.A., Differential thermal analysis of clay minerals and other hydrous materials. Part 1. Am. Min.: Journal of Earth and Planetary Materials, 27, 11, 746–761, 1942.

      79. Norton, F.H., Critical study of the differential thermal method for the identification of the clay minerals. J. Am. Ceram. Soc., 22, 1-12, 54–64, 1939.

      80. Grim, R.E., Differential thermal curves of prepared mixtures of clay minerals. Am. Mineral.: Journal of Earth and Planetary Materials, 32, 9–10, 493– 501, 1947.

      81. Graham, E.R., Primary minerals of the silt fraction as contributors to the exchangeable-base level of acid soils. Soil Sci., 49, 4, 277–282, 1940.

      82. Graham, E.R., Soil development and plant nutrition: II. Mineralogical and chemical composition of sand and silt separates in relation to the growth and chemical composition of soybeans. Soil Sci., 55, 3, 265, 1943.

      83. Graham, E.R., Soil Development and Plant Nutrition. I. Nutrient Delivery to Plants


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