Krypton in pore volume analysis

Van Wijngaarden, Korstiaan

05 1900

No description available.

Krypton

Gases Absorption and adsorption

Adsorption on activated carbon of methane, ethane, and ethylene gases and their mixtures and carbon dioxide at 212 K, 260 K, and 301 K and up to thirty-five atmospheres

Reich, Ricardo

12 1900

No description available.

Gases Absorption and adsorption

The effect of Aersol OT on the absorption of carbon dioxide by water in a wetted wall column

Engel, Lawrence James

08 1900

No description available.

Gases Absorption and adsorption

The use of nitrogen and ethane in surface area measurements by adsorption

Morris, Otto Marucci

08 1900

No description available.

Gases Absorption and adsorption

Particles

Investigation of gas equilibria in copper

Chia, Enrique Calixto

08 1900

No description available.

Copper

Gases Absorption and adsorption

A study of absorption by liquid drops

Engel, Lawrence James

12 1900

No description available.

Gases Absorption and adsorption

Adsorption of selected charge mutants of bacteriophage T4 lysozyme at silanized silica surfaces

Podhipleux, Nilobon

18 November 1994

The adsorption kinetics exhibited by selected charge mutants of T4 lysozyme at silanized silica surfaces were monitored with in situ ellipsometry. Mutant lysozymes were produced by substitution of lysine (Lys) with glutamic acid (Glu). Each substitution resulted in a decrease in the net charge of the protein by 2 units. The wild type lysozyme of net charge +9, and two mutants of net charge +7 and +5 were obtained from E. coli strain RR1 . Adsorption kinetics recorded at hydrophilic and hydrophobic interfaces were compared to the kinetic behavior predicted by two simple models for protein adsorption. One was a three-rate-constant model allowing for reversible adsorption followed by conversion to an irreversibly adsorbed form, and was analyzed under three different conditions. The first condition allowed the adsorption rate (k₁) and the desorption rate (k₋₁) to be variable while the surface-induced conversion rate (s₁) was assumed constant. The second condition assumed k₁ and k₋₁ constant instead of S₁, and the third allowed all kinetic rate constants to be variable. The second model allowed for irreversible adsorption into one of two states directly from solution. Both models suggested that substitution of Lys with Glu in the backbone of T4 lysozyme facilitates the adsorption of the protein at these interfaces. Proteins apparently adsorbed at the interfaces more tightly and occupied a greater interfacial area with substitution of Lys with Glu, and these effects were related to the location of the substitutions relative to other charged residues of the protein, and not to net charge. / Graduation date: 1995

Lysozyme -- Absorption and adsorption

URANIUM (VI) INTERACTIONS WITH MINERAL SURFACES: CONTROLLING FACTORS AND SURFACE COMPLEXATION MODELLING

Payne, Timothy Ernest, Civil & Environmental Engineering, Faculty of Engineering, UNSW

January 1999

The objective of the work described in this thesis was to improve the scientific basis for modelling the migration of U in the sub-surface environment. The project involved: ?? studying the sorption of U on model minerals (Georgia kaolinite and ferrihydrite) in laboratory experiments ?? carrying out experimental studies of U sorption on complex natural substrates ?? studying the mechanisms influencing U retardation in the natural environment, including transformation processes of iron oxides ?? identifying chemical factors which control U sorption on model and natural substrates ?? developing a mechanistic model for U sorption on ferrihydrite and kaolinite using the surface complexation adsorption model , and ?? assessing and modelling the effect of complexing ligands on uranyl adsorption. Uranium (VI) sorption on geological materials is influenced by a large number of factors including: pH, ionic strength, partial pressure of CO2, adsorbent loading, total amount of U present, and the presence of inorganic and organic ligands. The sorption of UO22+ typically increases with increasing pH (the 'low pH sorption edge') up to about pH 7. In systems equilibrated with air, there is a sharp decrease in sorption above this pH value (the 'high pH edge'), due to strong complexation between uranyl and carbonate. The adsorption model being used for ferrihydrite is a surface complexation model with a diffuse double layer, and both strong and weak sites for U sorption. Based on the analysis of EXAFS data, the U surface complexes were modelled as mononuclear bidentate surface complexes of the form (&gtFeO2)UO20. Ternary surface complexes involving carbonate with the form (&gtFeO2)UO2CO32- were also required for the best simulation of U sorption data. There was a slight decrease in U sorption on ferrihydrite in systems that contained sulfate. It was necessary to consider competition between UO22+ and SO42- for surface sites, as well as complexation between UO22+ and SO42- to model the data. The presence of citrate considerably reduced U sorption and caused dissolution of ferrihydrite. Complexation of citrate with both uranyl and ferric ions was taken into account in modelling this system. The model required the optimisation of the formation constant for a postulated mixed metal (U/Fe/citrate) aqueous complex. Humic acid increased U uptake at pH values below 7, with little effect at higher pH values. In terms of the amount of U sorbed per gram of adsorbent, U uptake on kaolinites KGa-1 and KGa-1B was much weaker than U uptake on ferrihydrite under similar experimental conditions. Electron microscope examination showed that titanium-rich impurity phases played a major role in the sorption of U by these standard kaolinites. A relatively simple model for uranyl sorption on the model kaolinites was able to account for U sorption under a wide range of experimental conditions. The model involved only three surface reactions on two sites (&gtTiOH and &gtAlOH), with a non-electrostatic surface complexation model. The relative amounts of the sites were estimated from AEM results. Precipitation was taken into account in modelling the experimental data obtained with high U concentrations. The effects of sulfate and citrate on U sorption by kaolinite were also assessed and modelled. Sulfate had a small effect on U sorption, which may be explained by aqueous complexation. Citrate had a greater effect, and this was not wholly explained by the formation of aqueous U-citrate complexes. The most likely explanation would also involve competition for surface sites between U and citrate. Uranyl uptake on ferrihydrite was greatly increased by the presence of phosphate. This was not due to precipitation, and was attributed to the formation of a ternary surface complex with a proposed structure of (&gtFeO2)UO2PO43-. The log K value for the formation of this complex was optimised using FITEQL. Phosphate also increased uptake of uranyl on kaolinite, and this was also attributed to the formation of ternary uranyl phosphate surface species. Uranium sorption on weathered schist samples from the vicinity of the Koongarra U deposit in northern Australia was generally similar to the model minerals (in terms of the effects of pH, ionic strength, total U, etc). Many experiments with the natural materials were spiked with an artificial U isotope (236U), which allowed adsorption (of 236U) and desorption (of 238U) to be distinguished, and provided a means of estimating the 'labile' or 'accessible' portion of the natural U content. A significant advantage of this method is that (unlike chemical extractions) it does not rely on the assumptions about the phases extracted by 'selective' reagents. Uranium sorption experiments were also carried out with Koongarra samples which had been treated with citrate / dithionite / bicarbonate (CDB) reagent to remove iron oxides. Uranium sorption was greatly decreased by the CDB extraction, which reduced the surface area of the samples by about 30-40%. To further elucidate the impact of iron minerals on U mobility in the natural environment, the transformation of synthetic ferrihydrite containing adsorbed natural uranium was studied. In these experiments, the ferrihydrite was partially converted to crystalline forms such as hematite and goethite. The uptake of an artificial uranium isotope (236U) and the leaching of 238U from the samples were then studied in adsorption / desorption experiments. The transformation of ferrihydrite to crystalline minerals substantially reduced the ability of the samples to adsorb 236U from solution. Some of the previously adsorbed 238U was irreversibly incorporated within the mineral structure during the transformation process. Therefore, transformation of iron minerals from amorphous to crystalline forms provides a possible mechanism for uranium immobilisation in the groundwater environment. In considering the overall effect on U migration, this must be balanced against the reduced ability of the transformed iron oxide to adsorb U. The experiments with the model and natural substrates demonstrated that trace impurities (such as Ti-oxides) and mineral coatings (such as ferrihydrite) can play a dominant role in U adsorption in both environmental and model systems. Although the various substrates had different affinities for adsorbing U, the effects of chemical factors, including pH, ionic strength, and carbonate complexation were similar for the different materials. This suggests that a mechanistic model for U sorption on model minerals may eventually be incorporated in geochemical transport models, and used to describe U sorption in the natural environment.

Uranium Absorption and adsorption

Hydration and swelling of clay mineral systems / a thesis submitted by Lance Arthur Graham Aylmore.

Aylmore, Lance Arthur Graham

January 1960

Typewritten / Includes bibliographical references. / Title page, contents and abstract only. The complete thesis in print form is available from the University Library. / Thesis (Ph.D.)--University of Adelaide, Dept. of Agricultural Chemistry, 1960

Clay Absorption and adsorption

Infiltration characteristics of soils in the Beaver Creek area of north central Arizona.

Rector, John Raymond,

January 1969

Thesis (M.S. - Watershed Management)--University of Arizona, 1969. / Includes bibliographical references (leaves 58-60).

Soil absorption and adsorption. Soils