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Synthesis and characterisation of basic magnesium carbonateBotha, Adele 10 October 2005 (has links)
Hydromagnesite, the most stable of the basic magnesium carbonates, can be obtained by mining or by synthesis. Existing synthetic procedures have certain drawbacks which include, undesirable environmental effluents or high pressure and/or temperature requirements. Due to the lack of information in the literature, the aim of this study was to develop a cost effective procedure for the synthesis of basic magnesium carbonate from Mg(OH)2, not hampered by the above mentioned drawbacks. Following an extensive investigation into various parameters that influenced the final product, a simple procedure, based on sparging CO2 through a slurry of magnesium hydroxide in water until the pH reached 7.5-8.5, was developed. The solid portion of the slurry is dried at 80 or 120°C to deliver an unidentified basic magnesium carbonate and hydromagnesite respectively. The products were characterised by XRD, TG-DTA, surface area determination, SEM and FT-IR. The rehydration characteristics of the products were also investigated. By combining the information obtained by each technique, valuable information could be obtained. The synthesised products were evaluated for flame retardant application, due to the demand of mineral flame retardants which could compete with Mg(OH)2 and AI(OH)3. Compared to the traditionally used halogenated flame retardants, the mineral flame retardants deliver non-toxic, non-corrosive decomposition products and contributes in suppressing the emission of smoke in a fire. Results indicated that the basic magnesium carbonates compared favourably to Mg(OH)2 and AI(OH)3 and presented several advantages in terms of flame retardant applications. Further tests will be necessary to accurately assess the flame retardant effect of the basic magnesium carbonates. The possibilities however seem promising. / Thesis (PhD (Chemistry))--University of Pretoria, 2006. / Chemistry / unrestricted
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A study of the hydrolysis of calcium and magnesium carbonatesBrowning, B. L. January 1928 (has links)
Thesis (Ph. D.)--University of Wisconsin--Madison, 1928. / Typescript. eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references (leaf 97).
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A method for the measurement of the thermal properties of hardened cement pastes and its use in the thermal characterisation of novel green cement bindersPatterson, Naomi January 2017 (has links)
No description available.
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Influence of carbonates of magnesium and calcium on bacteria of certain Wisconsin soilsFulmer, Henry Luman, January 1918 (has links)
Presented as Thesis (Ph. D.)--University of Wisconsin--Madison, 1917. / Cover title. Reprinted from Journal of agricultural research, vol. XII, no. 8 (25 Feb. 1918). Includes bibliographical references (p. 500-504).
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Microstructure, optical and electrical properties of Ni-MgO composites /Park, Hee Dong January 1986 (has links)
No description available.
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FT-Raman Spectroscopic Study of Calcium-Rich and Magnesium-Rich Carbonate MineralsMunshi, Tasnim, Edwards, Howell G.M., Jenlicka, J., Jorge Villar, Susana E. January 2005 (has links)
No / Calcium and magnesium carbonates are important minerals found in sedimentary environments. Although sandstones are the most common rock colonized by endolith organisms, the production of calcium and magnesium carbonates is important in survival strategies of organisms and as a source for the removal of oxalate ions. Extremophile organisms in some situations may convert or destroy carbonates of calcium and magnesium, which gives important information about the conditions under which these organisms can survive. The identification on the surface of Mars of 'White Rock' formations, in Juventae Chasma or Sabaea Terra, as possibly carbonate rocks makes the study of these minerals a prerequisite of remote Martian exploration. Here, we show the protocol for the identification by Raman spectroscopy of different calcium and magnesium carbonates and we present a database of relevance in the search for life, extinct or extant, on Mars; this will be useful for the assessment of data obtained from remote, miniaturized Raman spectrometers now proposed for Mars exploration.
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Mesoporous magnesium carbonate as a drug delivery vehicle for stabilising amorphous drugs and regulating their release rateZhang, Peng January 2016 (has links)
In today’s drug discovery, the number of candidate drugs based on new molecular entities with poor aqueous solubility is increasing. Since poor aqueous solubility of an active pharmaceutical ingredients (APIs) is associated with low bioavailability and thus limite their therapeutic effect, this is often a great challenge in the development of new drugs when oral administration is the preferred route of administration. A number of different strategies have been developed to circumvent this problem where salt formulations of an API is the most widely employed method. However, new strategies are needed since there is no one solution that solves this issue for all substances. In recent time, the concept of stabilizing poorly soluble APIs in their amorphous form has gained a lot of attention since amorphous compounds exhibit a higher apparent solubility compared to their crystalline counterparts. Amorphous substances are prone to crystallize if left in a non-constricted environment and thus need to be stabilized if the amorphous state is to be conserved until administration. Inorganic mesoporous materials have been proposed as an interesting type of excipients that can conserve the amorphous state of APIs. In this work, the focus was to investigate the possibilities of using a mesoporous type of magnesium carbonate to stabilize the amorphous state of different APIs. Due to the nanometer sized pores in the material, complete conservation of amorphous APIs was obtained. This resulted in both an increase in in vitro release rate and a higher solubility of the substances which may translate to both a faster onset of action and an improved therapeutic effect of the APIs in a clinical situation. The long term stability of formulations was also investigated showing promising results. The results presented in this work show that mesoporous magnesium carbonate represents an interesting type of excipient for oral formulations of APIs with poor aqueous solubility. / <p>Felaktigt ISBN 978-91-554-9702-6 i tryck version.</p>
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Phosphate recovery from water using cellulose enhanced magnesium carbonate pelletsMartin, Elisabeth 16 June 2017 (has links)
No description available.
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The Effect of Citric Acid on Amorphous Calcium Carbonate, Mesoporous Magnesium Carbonate and Calcium Magnesium Composite : A brief studyJafari, Abbas January 2021 (has links)
During the past decades, emission of greenhouse gases has accelerated to unsustainable levels. This is a serious issue that can have a devastating impact on everything from global economy to the terrestrial or marine ecosystem. A method for reducing the emission is named carbon capture and storage, which this project is based on. In this study, different concentrations of citric acid (CA) is used (as an additive) for the enhancement and optimization of carbon dioxid sorption properties of amorphous calcium carbonate (ACC), mesoporous magnesium carbonate (MMC) and calcium magnesium carbonate composite (CMC). These materials were heat treated in a calcination and an alternating carbonation process in order to study the carbon dioxid sorption performance. During the calcination process, CA undergoes a pyrolysis reaction in order to increase the specific surface area of the individual nanoparticles, which is an important factor for the sorption capacity. In the case of CMC, different molar ratios of magnesium oxide and calcium oxide were used in order to alter the concentration of the resulting magnesium oxide prior to heating. All three materials consisted of aggregations of nanometer-sized particles. Thermogravimetric analysis, scanning electron microscopy, surface area and porosimetry and infrared spectroscopy analysis suggest that the carbon dioxid sorption properties and the sintering stability of ACC and MMC do not improve since CA evaporates due to pyrolysis. Sintering was a greater problem for the evaluated CA treated ACC sample. However, in the case of CMC, the sorption and sintering properties were enhanced due to the higher Tamman-temperature of magnesium oxide, specifically for the lower concentration of magnesium oxide. After 19 carbonation cycles, CMC-1:1-25% CA showed signs of improved sintering stability and sorption capacity, compared to ACC-75% CA. / <p>Presentationen genomfördes på distans.</p>
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Mesoporous magnesium carbonate : Synthesis, characterization and biocompatibilityFrykstrand Ångström, Sara January 2016 (has links)
Mesoporous materials constitute a promising class of nanomaterials for a number of applications due to their tunable pore structure. The synthesis of most mesoporous materials involves a surfactant liquid crystal structure to form the pores. As well as the many advantages associated with this method of synthesis, there are disadvantages such as high production costs and a substantial environmental impact which limit the possibilities for large scale production. Therefore there is a need for other synthesis routes. The aim of the work described herein was to contribute to this field by developing a synthesis route that does not rely on surfactants for pore formation. A mesoporous magnesium carbonate material was therefore formed by self-assemblage of the particles around carbon dioxide gas bubbles, which functioned as pore templates. It was also possible to vary the pore diameter between 3 and 20 nm. The biocompatibility of the formed magnesium carbonate material was evaluated in terms of in vitro cytotoxicity and hemocompatibility, in vivo skin irritation and acute systemic toxicity. The results from the in vitro cytotoxicity, in vivo skin irritation and acute systemic toxicity test using a polar extraction vehicle showed that the material was non-toxic. While signs of toxicity were observed in the acute systemic toxicity test using a non-polar solvent, this was attributed to injection of particles rather than toxic leachables. In the in vitro hemocompatibility test, no hemolytic activity was found with material concentrations of up to 1 mg/ml. It was further shown that the material had anticoagulant properties and induced moderate activation of the complement system. The anticoagulant properties were ascribed to uptake of Ca2+. Finally, the ability of the material to increase the dissolution rate of the poorly soluble drug itraconazole was analyzed. Itraconazole was dissolved up to 23 times faster from the magnesium carbonate pores than when the free drug was used. The release rate from the delivery vehicle was dependent on the pore diameter. The work presented herein is expected to be useful for the development of alternative synthesis routes for mesoporous materials and also for encouraging the development of biomedical applications for these materials.
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