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31	Determination of the volume of solids, water and air and of moisture deficiency of soils Puri, Manohar Lall January 1949 (has links) No description available. 580 Soil science ; Soil chemistry
32	Changes in soil pH as a result of cation and anion diffusion Ramẓān, Muḥammad January 1970 (has links) No description available. 580 Soil chemistry ; Soil acidity
33	A study of factors influencing the equilibrium concentration of phosphate in soil White, Robert Edwin January 1962 (has links) No description available. 580 Soil chemistry ; Soils ; Salts in
34	Role of aluminum and iron hydroxy compounds in the absorption of organic matter by montmorillonite clay. Kadirgamathaiyah, Sinnathamby. January 1969 (has links) No description available. Soil chemistry Clay Soils -- Composition
35	Characteristics of humic substances and their removal behavior in water treatment Kim, Jong-Soo 05 1900 (has links) No description available. Humus Soil chemistry Water chemistry
36	The dissolution of mineral phosphate in soil Kirk, G. J. D. January 1985 (has links) The use of cheap, sparingly soluble calcium phosphate fertilizers is increasitgly widespread, particularly in the extensive agriculture systems of the tropics where very high yields are not sought, and phosphate deficiency is a major limitation to crop production. At present there is little quantitative understanding of the factors determining the rates of dissolution of calcium phosphates in soils. Existing quantitative treatments are inadequate, being either empirical or based on oversimplified theory. By developing a precise model of the dissolution process, it should be possible to short-cut the usual practice of running extensive field trials to establish the responses over a wide range of soil conditions and management practices. In this thesis a model which makes no arbitrary assumptions is developed for predicting the rates of dissolution of dicalcium phosphate dihydrate (DCPD) in soils. DCPD is the initial reaction product of the dissolution of many phosphatic fertilizers, and is an important fertilizer in its own right; the mechanisms governing its dissolution in soils are basically the same for other, more complex calcium phosphates. The simple case of a planar layer of DCPD in contact with soil is considered first to introduce the principles of the model. This is the simplest system for measuring experimentally the solute concentration profiles close to the dissolving surface, in order to test the model. The model is then extended to describe the dissolution of granules of DCPD in soil. The model comprises numerical solutions of mathematical equations describing the diffusion and reaction of calcium, phosphate and base in soil. The concentrations of calcium, phosphate and hydrogen ions in the soil solution at the mineral/soil boundary are found (a) from the ion activity product of DCPD and (b) by equating the fluxes of calcium, phosphate and base across the boundary (1 mol of DCPD gives 1 mol each of calcium, phosphate and base). In the granular system, the diminution of the granules as they dissolve, and the effect of neighbouring particles on each other are allowed for. The solute concentration profiles predicted for the planar system agreed with experimentally measured profiles; and the predicted net rates of dissolution of granules of DCPD agreed with the rates determined by a radioactive-tracer technique, in which <sup>45</sup>Ca dissolved from labelled DCPD is recovered from the soil with an extractant, saturated with respect to DCPD. Thus all important processes have been accounted for in the model. Since the theory is non-specific, the model should apply equally well to most other soils. The model has nine input parameters : the concentrations of calcium and phosphate in the native soil solution, the native soil pH, the phosphate and lime potential buffer capacities of the soil, the moisture status, the diffusion impedance factor, and the rate of application and particle size of the DCPD. A sensitivity analysis of the model showed that the rate is particularly dependent on particle size, rate of application, and the pH and concentration of calcium in the soil solution. If the granules are so stages the rate of dissolution is independent of the soil buffer terms. But for typical rates and methods of application, neighbouring granules will influence each other, and the consequent interactions between the rate determining variables are complex. The extension of the model to describe the dissolution of carbonateapatites, and hence rock phosphates, is discussed. 631.4 Soil chemistry : Phosphate minerals
37	Spatial distribution, chemistry and turnover of organic matter in soils / Golchin, Ahmad. January 1996 (has links) (PDF) Thesis (Ph. D.)--University of Adelaide, Dept. of Soil Science, 1997. / Copies of author's previously published works inserted. Includes bibliographical references (leaves 260-299). Humus Humus Soils Soil chemistry.
38	Hydrogen ion relationships in soils / Raupach, Maxwell. January 1953 (has links) (PDF) Thesis (M.Sc.)--University of Adelaide, 1953. / Typewritten copy.
39	The mineralogy and chemistry of the phosphate minerals in some soils / Sweatman, Thomas Rex. January 1961 (has links) (PDF) Thesis (M.Sc.) --University of Adelaide, Dept. of Geology, 1961. / Typewritten. Soils Soil chemistry. Soil mineralogy.
40	Factors contributing to lime requirements of soils and the evaluation of lime requirement tests Pionke, Harry Bernhard, January 1966 (has links) Thesis (M.S.)--University of Wisconsin--Madison, 1966. / eContent provider-neutral record in process. Description based on print version record. Bibliography: l. 159-168. Lime. Soil chemistry. Soils Soils

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