Influence of particle size on solubility of active pharmaceutical ingredients / E.C. Lubbe

Lubbe, Elizabeth Cornelia

January 2012

The aqueous solubility of an active pharmaceutical ingredient (API) is an important property that requires evaluation during early development and prior to formulation of the final product. With general, experimental, solubility testing of different APIs, the question always arises as to whether particle size had been determined beforehand or not. All available literature suggests that particle size, for pharmaceutical powders, does not significantly affect equilibrium solubility. The dissolution rate will differ according to different particle sizes, but the overall results should be identical after equilibrium is established. This study was therefore planned to investigate as to whether different particle size fractions of the same API, dissolving at different rates, would all reach solubility equilibrium within 24 hours. Also, APIs from different solubility classes were investigated, because poorly soluble substances would most likely require a longer period of time to equilibrate. The time period of 24 hours was selected, because many published solubility studies report using that interval and is it the standard for our research group also. Available APIs were selected to determine the influence (if any) of particle size on their equilibrium solubilities and the time required for attaining that status. For the purpose of this investigation, five APIs were selected from compounds at our disposal in-house, ranging from freely soluble to poorly soluble in the order: chloroquine phosphate > pyrazinamide > mefloquine hydrochloride > closantel sodium > roxithromycin. Solubility studies were successfully completed on four of the five APIs selected. For closantel sodium, pyrazinamide and roxithromycin it was demonstrated that the 24 hour test period was sufficient for the attainment of equilibrium solubility, regardless of the particle size fractions tested. Surprisingly, the only API in this study for which 24 hours was an insufficient test period was mefloquine HCl, which was not the least soluble compound tested. Further testing would be required to clarify this anomaly. What was evident from the outcomes of this investigation was that although the ubiquitous 24 hour solubility test may work well in many cases, its suitability should be reviewed on a case-by-case basis and not just for the most poorly soluble compounds. Researchers testing solubility at temperatures lower than 37°C should be especially cautious of using a standardised test period, because equilibrium solubility would take longer to achieve with less energy available to the system. / Thesis (MSc (Pharmaceutics))--North-West University, Potchefstroom Campus, 2013

Particle size

Solubility

Closantal sodium

Chloroquine phosphate

Mefloquine hydrochloride

Pyrazinamide

Roxithromycin

The effect of filler, active ingredient and Kollidon® VA64 sollubility on the release profile of the active ingredient from wet granulation tablet formulations

Claassen, Petrus Jacobus

January 2012

There are mainly two manufacturing processes used in the pharmaceutical industry, namely direct compression and granulation of which granulation can be subdivided into wet granulation and dry granulation. Wet granulation is a process still widely used in the pharmaceutical industry and provides better control of drug content uniformity and compactibility at low drug concentrations. Lactose monohydrate and microcrystalline cellulose (MCC) were used as fillers in this study. Both these fillers possess unacceptable powder flow properties and the use of wet granulation may improve this property. One of the advantages of lactose monohydrate over MCC is that it is partially water soluble. A fractional factorial design was used in this study. Twelve tablet formulations were formulated containing different combinations of active ingredients (furosemide or pyridoxine hydrochloride), fillers (lactose monohydrate or MCC) and a binder (Kollidon® VA64) in three different concentrations (0.75, 1.5 or 3.0% w/w). The binder was used to produce granules by means of wet granulation, using ethanol as granulating fluid. The granules were dried in an oven and screened through different sized sieves to produce the final granulated powder formulations ready for tableting. A disintegrant (Ac-di-sol®) and lubricant (magnesium stearate) were incorporated into the granulated powder formulations extra-granular (0.5% w/w) and were kept as a constant in this study throughout all the formulations. A Turbula® mixer was used to mix the granulated powder formulations for a constant 5 minutes. During the first phase of the study, tablets were compressed using 2 compression settings (22 and 24). These compression settings were used to determine what effect different external pressures would have on the different tablet properties. Tablet weight for all the formulations was kept constant at 250 mg, although the volume of the matrix differed for each tablet formulation. The physical properties of the tablets were evaluated with regard to weight variation, mechanical strength (crushing strength and friability) and disintegration. Tablet formulation 12 yielded unsatisfactory tablets, due to poor powder flow into the die. Tablet formulations that contained the highest binder concentration (3.0% w/w) and were compressed at the highest compression setting (24) (formulations 4 and 9), exhibited the highest mechanical strength. The disintegration results revealed that the tablet formulations containing MCC as filler disintegrated faster compared to those containing lactose monohydrate. The increase in binder concentration caused an increase in mechanical strength, possibly decreasing tablet porosity, therefore prolonging disintegration time due to impeded water penetration into the tablet matrix. During the final phase of the study, dissolution studies were conducted on the different tablet formulations in 0.1 M HCl for 120 minutes. In terms of dissolution results, the initial dissolution rate (DRi) and extent of dissolution (AUC) were compared. It was found that the tablet formulations containing pyridoxine hydrochloride as active pharmaceutical ingredient (API) exhibited faster drug dissolution (higher DRi and AUC-values) compared to those tablet formulations containing furosemide. The faster dissolution exhibited by the pyridoxine hydro- chloride containing formulations can possibly be attributed to the fact that pyridoxine hydrochloride is good water soluble whereas furosemide is practically insoluble in water. The effect of the filler depended on the aqueous solubility of the filler and the concentration of the binder (Kollidon VA64) employed. An increase in binder concentration led to a decrease in the initial rate of dissolution as well as the extent of drug dissolution. In the case of the pyridoxine hydrochloride containing formulations, formulation 9 exhibited the slowest DRi and lowest extent of drug dissolution (1.40 ± 0.03 µg.cm-3.min-1 and 2396.52 ± 26.43 µg.cm-3.min respectively). In the case of the furosemide containing formulations, formulation 4 exhibited the slowest DRi and lowest extent of drug dissolution (0.22 ± 0.07 µg.cm-3.min-1 and 1018.62 ± 59.74 µg.cm-3 min respectively). In both cases, the formulations contained Kollidon VA64 in a concentration of 3% w/w and were compressed at compression setting 24. The disintegration process of tablets goes hand in hand with the dissolution process and results have shown that by establishing rapid contact between drug particles and the surrounding medium proves to be a necessity for rapid drug dissolution. Disintegration does not assure drug dissolution, but when prolonged, slower dissolution rates can be obtained, implying a slow rate and low extent of drug dissolution. The disintegrant in this study was incorporated extra-granular ensuring rapid tablet disintegration. However, due to binder concentration of 3% w/w, granule disintegration was probably negatively affected resulting in a lower drug surface area exposed to the surrounding dissolution medium, leading to a slower initial rate and extent of drug dissolution. From the results obtained during this study it was evident that formulation variables such as the type of filler, the concentration of the binder and compression setting employed during tablet manufacturing can have a ronounced effect on the pharmaceutical availability of the active ingredient. However, the extent of the effect was dependent on the aqueous solubility of the active ingredient. / Thesis (MSc (Pharmaceutics))--North-West University, Potchefstroom Campus, 2013.

Granulation

Furosemide

Pyridoxine hydrochloride

Fillers

Water solubility

Dissolution

Granulering

Furosemied

Piroksienhidrochloried

Vulstowwe

Wateroplosbaarheid

Dissolusie

The Solubility and Metal-silicate Partitioning of Some Highly Siderophile Elements: Implications for Core-formation and Planetary Accretion

Bennett, Neil

19 June 2014

Understanding Earth’s accretion and primary differentiation is a long-standing goal of geology. The segregation of FeNi metal from molten silicate to form Earth’s core is expected to deplete and fractionate the highly siderophile elements (HSEs). Estimates of the primitive upper mantle (PUM) composition however, reveal only modest HSE depletions and chondritic element ratios. Past experiments to determine if the mantle composition is set by high-temperature metal-silicate equilibrium have involved measuring the solubility of HSEs in silicate melt at conditions more reducing than the iron-wustite (IW) buffer. Accurate determination of solubilities at such conditions has been hindered by the formation of dispersed metal inclusions; this work describes methods to circumvent the problem. Results of three separate studies are presented which document the solubility of Re, Pt and Au in molten silicate which is demonstrably nugget-free. Data obtained from experiments done at 0.1 MPa–2 GPa, 1573–2573 K and ~ IW -1.5 to +3 reveal: 1) Re, Pt and Au solubility increases with increasing temperature, 2) Re solubility increases with increasing oxygen fugacity (fO2), consistent with dissolution as oxide species, 3) Below ~ IW +3, Pt and Au solubility increases with decreasing fO2, consistent with dissolution as neutral or silicide species, and 4) that Au is amongst the most soluble HSE in molten silicate, with values increasing with temperature, but insensitive to changes in P, fO2 and melt composition, making it well suited as a geothermometer for core formation. Partition coefficients calculated from these and previous solubility measurements indicate that metal-silicate equilibrium is unable to reproduce the Re/Os and Pt/Os ratios required by PUM Os isotope systematics if simultaneously accounting for the observed absolute element abundances. Instead, results support late accretion of material following core formation, elevating element abundances and endowing chondritic inter-element ratios. Experimental results are incorporated into a terrestrial accretion model, which differs from the standard approach by explicitly accounting for the distribution of oxygen. Model results show siderophile element abundances in PUM are best reproduced if the mantle undergoes oxidation during accretion and metal-silicate equilibrium occurs near the peridotite solidus.

Accretion

Core

Rhenium

Platinum

Gold

Partitioning

Silicate Melt

Metal

Temperature

Pressure

Fugacity

Solubility

0996

0372

The Solubility and Metal-silicate Partitioning of Some Highly Siderophile Elements: Implications for Core-formation and Planetary Accretion

Bennett, Neil

19 June 2014

Understanding Earth’s accretion and primary differentiation is a long-standing goal of geology. The segregation of FeNi metal from molten silicate to form Earth’s core is expected to deplete and fractionate the highly siderophile elements (HSEs). Estimates of the primitive upper mantle (PUM) composition however, reveal only modest HSE depletions and chondritic element ratios. Past experiments to determine if the mantle composition is set by high-temperature metal-silicate equilibrium have involved measuring the solubility of HSEs in silicate melt at conditions more reducing than the iron-wustite (IW) buffer. Accurate determination of solubilities at such conditions has been hindered by the formation of dispersed metal inclusions; this work describes methods to circumvent the problem. Results of three separate studies are presented which document the solubility of Re, Pt and Au in molten silicate which is demonstrably nugget-free. Data obtained from experiments done at 0.1 MPa–2 GPa, 1573–2573 K and ~ IW -1.5 to +3 reveal: 1) Re, Pt and Au solubility increases with increasing temperature, 2) Re solubility increases with increasing oxygen fugacity (fO2), consistent with dissolution as oxide species, 3) Below ~ IW +3, Pt and Au solubility increases with decreasing fO2, consistent with dissolution as neutral or silicide species, and 4) that Au is amongst the most soluble HSE in molten silicate, with values increasing with temperature, but insensitive to changes in P, fO2 and melt composition, making it well suited as a geothermometer for core formation. Partition coefficients calculated from these and previous solubility measurements indicate that metal-silicate equilibrium is unable to reproduce the Re/Os and Pt/Os ratios required by PUM Os isotope systematics if simultaneously accounting for the observed absolute element abundances. Instead, results support late accretion of material following core formation, elevating element abundances and endowing chondritic inter-element ratios. Experimental results are incorporated into a terrestrial accretion model, which differs from the standard approach by explicitly accounting for the distribution of oxygen. Model results show siderophile element abundances in PUM are best reproduced if the mantle undergoes oxidation during accretion and metal-silicate equilibrium occurs near the peridotite solidus.

Accretion

Core

Rhenium

Platinum

Gold

Partitioning

Silicate Melt

Metal

Temperature

Pressure

Fugacity

Solubility

0996

0372

Percutaneous absorption of cyclizine and its alkyl analogues / Lesibana Mishack Monene

Monene, Lesibana Mishack

January 2003

Percutaneous delivery of drugs promises many advantages over oral or intravenous administration, such as a better control of blood levels, a reduced incidence of systemic toxicity, an absence of hepatic first-pass metabolism, better patient compliance, etc. However, the dermal drug transport is limited by the unsuitable physicochemical properties of most drugs and the efficient barrier function of the skin. Thus, numerous attempts have been reported to improve topical absorption of drugs, concentrating mainly on the barrier function of the stratum corneum by use of penetration enhancers and/or skin warming. An alternative and interesting possibility for improved dermal permeability is the synthesis of derivatives or analogues with the aim of changing the physicochemical properties in favour of skin permeation, efficacy and therapeutic value. Cyclizine (I) is an anti-emetic drug primarily indicated for the prophylaxis and treatment of nausea and vomiting associated with motion sickness, post operation and Meniere's disease. It acts both on the emetic trigger zone and by damping the labyrinthine sensitivity. Pharmacologically it has anti-histaminic, antiserotonergic, local anaesthetic and vagolytic actions. It is widely used and also suitable for children from six year of age. Percutaneous absorption of (I) can, among others, avoid the "first-pass" effect and the discomfort of injection. The main objective of this study was to explore the feasibility of percutaneous absorption of (I) and its alkyl analogues via physicochemical characterization and assessment of their permeation parameters. The intent was also to establish a correlation between the physicochemical properties of these compounds and their percutaneous rate of absorption. To achieve these objectives, the study was undertaken by synthesizing the alkyl analogues and determining the physicochemical parameters relevant to skin transport. Identification and level of purity for the prepared analogues were confirmed by mass spectrometry (MS), nuclear magnetic resonance (NMR) spectrometry and infrared (IR) spectrometry. Experimental aqueous solubility (25 °c & 32 °C) and partition coefficient for each compound were determined. In vitro permeation studies were performed at pH 7.4, using Franz diffusion cells with human epidermal membranes. Diffusion experiments were conducted over a period of 24 hours maintaining a constant temperature (37 DC) by means of water bath. All samples were analysed by high pressure liquid chromatography (HPLC). Cyclizine (I) has a methyl group at N-4. Increasing the alkyl chain length on N-4 of the piperazine ring resulted' in compounds with lower melting points and higher water solubility than (I). (II) exhibited 3-fold increase in water solubility, followed by (IV) with about 2.5 fold increase. The water solubility of (III) was almost the same as that of (I). Log partition coefficients increased linearly with increasing alkyl chain length. The analogues therefore, possessed more favourable physicochemical properties to be delivered percutaneously. Indeed, the in vitro skin permeation data proved that these analogues could be delivered more easily than (I) itself. The flux of (I) was 0.132 ug/cm2/h in a saturated aqueous solution. Compound (II) resulted in a 53-fold (6.952 ug/cm2/h) increase in permeation compared to (I). (III) and (IV) resulted in a 2- and 5fold enhancement of permeation respectively. Based on the results of the study, it seems that increased aqueous solubility and low level of crystallinity play a vital role in optimizing percutaneous absorption of (I) and its alkyl analogues. But the importance of the effect of increased lipophilicity cannot be ignored. The low percutaneous• absorption of (I) might be attributed to its low aqueous solubility and increased crystallinity, as is evident from the higher melting point than the analogues. From all the permeability data using aqueous solutions, it is clear that compound (II) is the best permeant of this series and in addition it is known that this compound antagonizes the effects of histamine. / Thesis (M.Sc. (Pharm.))--North-West University, Potchefstroom Campus, 2004.

Percutaneous absorption

Cyclizine

Alkyl analogues

Physicochemical properties

Aqueous solubility

Partition coefficient

Melting point

Study of Properties of Cryolite – Lithium Fluoride Melt Containing Silica

Thomas, Sridevi

28 November 2012

The ultimate goal of this study is to examine the feasibility of extracting silicon from silica through electrolysis. The objective of the thesis was to evaluate the physico-chemical properties of a cryolite-lithium fluoride mixture as an electrolyte for the electrolysis process. A study of 86.2wt%Cryolite and13.8wt%Lithium fluoride melt with silica concentration varying from 0-4wt% and temperature range of 900-1000°C was done. Three properties were measured using two sets of experiments: 1) Dissolution Behaviour Determination, to obtain a) solubility limit, b) dissolution rate (mass transfer coefficient) and 2) density using Archimedes’ Principle. The study concluded that solubility and dissolution rate increases with temperature and the addition of LiF to cryolite decreases the solubility limit but increases the rate at which silica dissolves into the melt. With addition of silica, the apparent density of electrolyte first increases up to 2-3wt% and the drops.

cryolite

silica

lithium fluoride

dissolution

solubility

density

conductivity

mass transfer coefficient

0794

0743

Topology and Dynamics of Macromolecular Aggregates Studied by Pressure NMR

Al-Abdul-Wahid, Mohamed Sameer

06 December 2012

The topology and dynamics of biomolecules are intricately linked with their biological function. The focus of this thesis is the NMR-based measurement of topology and dynamics in biomolecular systems, and methods of measuring immersion depth and orientation of membrane-associated molecules. In detergent micelles and lipid bilayers, the local concentrations of hydrophobic and hydrophilic molecules are a function of their bilayer immersion depth. For paramagnetic molecular oxygen or metal cations, the magnitudes of the associated paramagnetic isotropic contact shifts and relaxation rate enhancements (PREs) are therefore depth-dependent. NMR measurements of these effects reveal the immersion depth of bilayer- or detergent-associated molecules. This work first explores transbilayer oxygen solubility and thermodynamics, as measured from contact shifts and PREs of the constituent lipid molecules in the presence of 30 bar oxygen. Contact shifts revealed the transmembrane O2 solubility profile spans a factor of seven across the bilayer, while PREs indicated that oxygen partitioning into bilayers and dodecylphosphocholine (DPC) micelles is entropically driven. Next, this work describes how paramagnetic effects from molecular oxygen and Ni(II) cations may be employed to study the immersion depth and topology of drug and protein molecules in DPC micelles. In one study, the positioning of the amphipathic drug imipramine in micelles was determined from O2- and Ni(II)-induced contact shifts. A second study, relying solely on O2-induced PREs, determined the tilt angles and micelle immersion depths of the two alpha helices in a monomeric mutant of the membrane protein phospholamban. A third study utilized 19F NMR to explore the importance of juxtamembraneous tryptophans on the topology of the membrane protein synaptobrevin, via O2-induced contact shifts and solvent-induced isotope shifts of a juxtamembraneous 19F-phenylalanine. Comparison of synaptobrevin constructs with zero, one, and two juxtamembraneous tryptophans revealed that while one tryptophan is sufficient to ‘anchor’ the protein in micelle, the addition of a second tryptophan dampens local dynamics. These solution state NMR studies demonstrate how paramagnetic effects from dissolved oxygen, complemented with measurements of local water exposure, provide detailed, accurate descriptions of membrane immersion depth and topology. These techniques are readily extended to the study of a wide range of biomolecules.

nuclear magnetic resonance spectroscopy

membrane proteins

membrane topology

protein dynamics

paramagnetic NMR

oxygen solubility

0847

Importance of protein-protein interactions on protein crystallisation

Chirag Mehta

Unknown Date

There is a strong link between solubility, and thus crystallisation, and the molecular interactions of proteins in dilute salt solutions. Such molecular interactions are governed by the weak interaction forces (electrostatic, hydration and hydrophobic). Such forces can be quantitatively estimated in terms of a second virial self-coefficient (B22) and a second virial cross-coefficient (B23) for a single and a binary protein system, respectively. Previous studies confirmed the relation between a value of the second virial coefficient and a type of interaction (attractive or repulsive). The aim of this thesis is to correlate the second virial coefficient with the solubility and nucleation for single and binary protein systems. Model proteins used in this work are lysozyme and ovalbumin from egg-white, and α-amylase from Bacillus Licheniformis (BLA). The measurements are performed for sodium chloride and ammonium sulphate solutions in an acidic pH at 20 oC. Interaction chromatography is used in this work to estimate the B22 and B23 values for the model proteins in salt solutions. From the measured values of B22 and B23, the type of interaction is generalised as a function of the salt type, salt concentration, pH and protein type. For the single protein systems, in ammonium sulphate solutions (0.1 - 2.4 M) at pH 4.0 and 7.0, repulsion or no interactions are observed below 0.8 M and, as the salt concentrations are increased attractive self-interactions are observed for the model proteins. However, for the sodium chloride solutions (0.1 - 2.0 M) at pH 4.0 and 7.0, the interaction patterns vary with the salt concentration, the pH and the type of protein studied. A common feature of the self-interaction for all the model proteins is the attractive interactions close to the isoelectric point. For the binary protein systems, three distinct regions are observed in the ammonium sulphate solutions (0.1 - 1.6 M) at pH in the range 4.0 - 7.0. Attractive or no cross-interactions are observed at low salt concentrations (< 0.5 M). At the intermediate salt concentrations (0.5 - 1.0 M), the cross-interactions are constant and near zero. This is followed by a sharp increase in the attractive interactions above 1.0 M ammonium sulphate concentrations. However, for sodium chloride solutions (0.1 - 1.6 M) at pH 4.0 - 7.0, two distinct regions are observed. Attraction or no interactions are observed at low salt concentrations (< 0.5 M) and above 0.5 M concentrations of sodium chloride, negligible cross-interactions are observed between model proteins. For the single protein system, an overall increase in the solubility of three model proteins is observed with an increase in the concentrations of ammonium sulphate and also for sodium chloride solutions except for BLA, where a salting-in behaviour is observed. Linear regression is used on the solubility data to determine the parameters of the Cohn equation (β and Ks) where the values of β vary with solution pH, protein type and salt type. The values of Ks vary with protein type and salt type. However, it is insensitive to the solution pH for lysozyme in ammonium sulphate, ovalbumin in sodium chloride and BLA in ammonium sulphate solutions. For the binary protein system, the presence of ovalbumin had a measurable effect on lysozyme solubility at pH < 5.0 in both salts. In low concentration sodium chloride solutions (< 0.3 M), a decrease in the solubility of lysozyme was observed with the presence of ovalbumin at acidic pH < 5.0. However, in ammonium sulphate solutions, the lysozyme solubility increases with the addition of ovalbumin in the salt concentration range 1.6 - 2.0 M and at pH < 4.0. The primary nucleation threshold values are also determined for lysozyme in sodium chloride and ammonium sulphate solutions. In sodium chloride solutions (0.2 - 1.0 M), the critical supersaturation values increase as the solution pH is raised from 4.0 to 7.0; however in ammonium sulphate solutions (1.0 - 2.0 M), the reverse effect is observed. The critical supersaturation required to nucleate lysozyme in ammonium sulphate solutions is approximately three times higher than in sodium chloride solutions. For the single protein systems, the measured values of solubility and B22 were correlated using published models (RSL and HDW). For each protein-salt combination, a reasonable single correlation between solubility and B22 is possible as the salt concentrations and pH are varied. There are separate correlations for sodium chloride and ammonium sulphate solutions. Based on the correlation curve of solubility and B22, it is proposed that the acidic pH range (4.0 - 5.0) is better for crystallising and precipitating globular proteins from these salt solutions. If the values of solubility and B22 are converted into a non-dimensional quantity, the data derived from the different protein-salt systems collapse onto a single curve for the same salt type. The B22 values are also correlated with the critical supersaturation (ln(c*/S)) for the primary nucleation of lysozyme in salt solutions. The values of the critical supersaturation increase as the values of the second virial coefficient become negative or reduce. The ideal critical supersaturation required to create nuclei of lysozyme in salt solutions is between 0.1 and 1.4. For the binary protein systems, B23 values were related to the slope of the lysozyme and ovalbumin plot at same salt concentration and solution pH. Further work is required for binary protein systems to generalise such correlations as a function of the salt concentration and pH. The correlations derived in this thesis are useful generally to predict the solubility and primary nucleation of globular protein in salt solutions. This work reinforces the importance of the second virial coefficient in predicting the crystallisation of protein in salt solutions.

protein solubility

primary nucleation

second virial coefficient

Interaction Chromatography

Binary Mixture

Solution Chemistry of some Dicarboxylate Salts of Relevance to the Bayer Process

A.Tromans@chem.murdoch.edu.au, Andrew John Tromans

January 2001

This thesis deals with certain aspects of the solution chemistry of the simple dicarboxylate anions: oxalate, malonate and succinate, up to high concentrations. These ions are either significant impurities in the concentrated alkaline aluminate solutions used in the Bayer process for the purification of alumina, or are useful models for degraded organic matter in industrial Bayer liquors. Such impurities are known to have important effects on the operation of the Bayer process. To develop a better understanding of the speciation of oxalate (the major organic impurity in Bayer liquors) in concentrated electrolyte solutions, the formation constant (Log£]) of the extremely weak ion pair formed between sodium (Na+) and oxalate (Ox2ƒ{) ions was determined at 25 oC as a function if ionic strength in TMACl media by titration using a Na+ ion selective electrode. Attempts to measure this constant in CsCl media were unsuccessful probably because of competition for Ox2ƒ{ by Cs+. Aqueous solutions of sodium malonate (Na2Mal) and sodium succinate (Na2Suc) were studied up to high (saturation) concentrations at 25 oC by dielectric relaxation spectroscopy (DRS) over the approximate frequency range 0.1 „T £h/GHz „T 89. To complement a previous study of Na2Ox, formation constants of the Na+-dicarboxylate ion pairs were determined and they were shown to be of the solvent-shared type. Both the Mal2ƒ{ and Suc2ƒ{ ions, in contrast to Ox2ƒ{, were also shown to possess large secondary hydration shells Apparent molal volumes (Vf) and heat capacities at constant pressure (Cpf) of aqueous solutions of Na2Ox, Na2Suc, Na2Mal and K2Ox were determined at 25 oC up to their saturation limits using vibrating tube densitometry and flow calorimetry. These data were fitted using a Pitzer model. The adherence of Vf and Cpf of various Na+ and K+ salts to Young¡¦s rule was examined up to high concentrations using the present and literature data. Young¡¦s rule was then used to estimate hypothetical values of Cpf and Vf for the sparingly soluble Na2Ox at high ionic strengths, which are required for the thermodynamic modelling of Bayer liquors. The solubility of Na2Ox in various concentrated electrolytes was measured, at temperatures from 25 oC to 70 oC in media both with (NaCl, NaClO4, NaOH) and without a common ion (KCl, CsCl, TMACl). The common ion effect was found to dominate the solubility of Na2Ox. The solubility of calcium oxalate monohydrate (CaOx„ªH2O) was also determined. The solubilities of both Na2Ox and CaOx„ªH2O in media without a common ion increased with increasing electrolyte concentration, except in TMACl media, where they decreased. The solubility of Na2Ox was modelled using a Pitzer model assuming the Pitzer parameters for Na2SO4 and minimising the free energy of the system. The data were modelled successfully over the full concentration and temperature range of all the electrolytes, including ternary (mixed electrolyte) solutions.

sodium

oxalate

mlonate

succinate

pitzer

Dielectric relaxation spectrascopy

heat capacity

solubility

ion paring

Long-term fate of sewage-sludge derived cadmium in arable soils : laboratory and field experiments, and modelling with SLAM and WHAM /

Bergkvist, Petra,

January 2003

Diss. (sammanfattning). Uppsala : Sveriges lantbruksuniv., 2003. / Härtill 3 uppsatser.