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SIMULATION OF MECHANICAL, THERMODYNAMIC, AND MAGNETIC PROPERTIES OF MAGNESIA WITH SUBSTITUTIONAL ELEMENTS FOR IMPROVED MAGNETIC CORE COATING APPLICATIONSAsimiyu Ajileye Tiamiyu (8035247) 04 December 2019
<p>In transformers used in
the electrical industry, a coating, such as magnesium oxide or magnesia (MgO),
is needed to coat the magnetic ferrite core, such as silicon steel. The coating
is to provide electrical insulation of the layers of the ferrite core material,
in order to reduce its heat dissipation loss. The coating also separate the
layers of the coiled materials to prevent their sticking or welding during high
temperature uses. </p>
<p> </p>
<p>The goal of this thesis is
to perform a modeling study to understand the mechanical, thermodynamic, magnetic
and thermal properties of pure and M-doped (M stands for Mn, Co, or Ni) magnesia,
thus providing a theoretical understanding of the application of this group of
coating materials for transformer applications. </p>
<p> </p>
<p>The study has the
following sections. The first section is focused on the mechanical properties
of pure magnesia. Using density functional theory (DFT) based calculations, the
computed Young’s modulus, Poisson’s ratio, bulk modulus, and compressibility
are 228.80 GPa, 0.2397, 146.52 GPa, and 0.00682, respectively, which are in
good agreement with the literature data. Using molecular dynamics (MD)
simulations, the computed Young’s modulus is 229 GPa. Using discrete element
model (DEM) approach, the bending deformation of magnesia is simulated.
Finally, using finite element model (FEM), micro-hardness indentation of
magnesia is simulated, and the computed Brinell hardness is 16.1 HB, and
Vickers hardness is 16 GPa.</p>
<p> </p>
<p>The second section is on
the thermodynamic and physical properties of pure and doped magnesia. Using DFT
based simulations, the temperature-dependent thermodynamic properties, such as
free energy, enthalpy, entropy, heat capacity at constant volume, and Debye
temperature of magnesia, are computed. The X-ray powder diffraction (XRD)
spectra of M-doped magnesia are simulated, at the doping level of 1.5%, 3%, 6%
and 12%, respectively. The simulated XRD data show that peaks shift to higher
angles as the doping level increases. </p>
<p> </p>
<p>The third section is on
the magnetic properties of pure and doped magnesia. Using DFT based
simulations, the calculated magnetic moments increase with the doping level,
with Mn as the highest, followed by Co and Ni. This is due to the fact that Mn
has more unpaired electrons than Co and Ni. </p>
<p> </p>
The
fourth section is on the thermal properties of the pure magnesia. Using the Reverse
Non-Equilibrium Molecular Dynamics (RNEMD) method, the computed thermal conductivity of magnesia is 34.63 W/m/K, which is in
agreement with the literature data of 33.0 W/m/K at 400 K.
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Dietary Sodium Bicarbonate and Magnesium Oxide for Early Postpartum Lactating Dairy Cows: Effect upon Milk Coagulation Parameters.Lee, Shu-Chuan 01 January 1985 (has links)
Forty-eight Holstein cows at Utah State Dairy Farm were blocked statistically according to date of calving, previous milk production, and numbers of lactation at parturition. The cattle were assigned randomly to one of four treatments within blocks. The four treatments included a base ration (control, treatment #1), base ration plus .8% of sodium bicarbonate (treatment #2), base ration plus .4% of magnesium oxide (treatment #3), and base ration plus both .8% of sodium bicarbonate and .4% of magnesium oxide (treatment #4). The research was conducted from February 1983 to November 1984. A formagraph was used to measure milk coagulation parameters and pH was determined.
There was no significant difference in milk coagulation parameters or pH between the control and the buffer treatments. Milk parameters were significantly different in individual cow, week, and milk pH. Milk parameters did not appear to be dependent upon season. Curd firmness was significant in interaction of season and treatment. Significant variations in milk pH were observed in relation to week, season, and individual cow.
Overall treatments, the clotting time, K20, and pH value increased each week, and A30 decreased each week. The milk parameters and pH in each treatment were significant between weeks except K20 and A30 in treatment #3, and A30 in treatment #2 (p>0.05). The clotting time and K20 were negatively correlated with firmness, and there was positive correlation between Ct and K20 as expected.
Somatic cell count was positively correlated with clotting time, K20, and pH and negatively correlated with A30. Milk pH was the most significant and had positive correlation coefficient with clotting time and firming rate and negative correlation coefficient with curd firmness.
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[en] PRELIMINARY STUDY OF MAGNESIUM OXIDE MACROPOROUS MEMBRANE SINTERING / [pt] ESTUDO PRELIMINAR DA SINTERIZAÇÃO DE MEMBRANAS MACROPOROSAS DE ÓXIDO DE MAGNÉSIOLEYDI DEL ROCIO SILVA CALPA 13 April 2012 (has links)
[pt] O presente trabalho apresenta um estudo preliminar sobre a síntese de membranas macroporosas de óxido de magnésio, com uma faixa de porosidade estreita e homogênea, mediante uma técnica reprodutível e visando sua aplicação futura na separação de substâncias gasosas impossíveis de serem separadas por métodos convencionais. As membranas foram criadas a partir da sinterização das respetivas nanopartículas obtidas pelo método sol-gel/nano matriz, usando nitrato de magnésio como precursor principal e álcool polivinílico, PVA, como matriz das nanoestruturas. Foram avaliados diferentes parâmetros de pressão e temperatura de sinterização. As amostras obtidas foram analisadas por MEV, DRX, BET e Porosimetria por Intrusão de Mercúrio (PIM). Os resultados mostram que o material obtido apresenta tamanho de partículas uniforme, confirmando assim a sinterização. O tamanho de cristalito médio foi de 160nm, sendo que o tamanho médio de grãos foi de 450nm; os materiais que apresentaram melhores propriedades foram aqueles sinterizados a 1000 e 1100 graus Celsius com pressão de 173MPa, e a 1000 graus Celsius com 260MPa. A macroporosidade obtida se encontra numa faixa muito perto do limite com a mesoporosidade, sendo que quase 97 por cento dos macroporos estão entre 50 e 150nm de raio. Os resultados indicam que a técnica foi reprodutível e a faixa de poros é razoavelmente estreita, o que permitirá aplicar a membrana na separação de substâncias específicas. / [en] This work present a preliminary study on the synthesis of macroporous membranes of magnesium oxide with a homogeneous and a narrow range of porosity obtained by a reproducible technique, which aims their future application in the separation of gaseous substances impossible to separate by conventional techniques. The membranes were obtained by the sintering of the respective nanoparticles which were obtained by the sol-gel/nanotemplate technique, using a magnesium nitrate as the main precursor and polyvinyl alcohol, PVA, as a template of the nanostructures. Pressure and Temperature were the sintering parameters evaluated in the present research. The samples obtained were analyzed by SEM, XRD, BET, and Intrusion Mercury Porosimetry (IMP). The results show uniformity in the particles size of the material, confirming the sintering process. The average crystallite size was 160nm, and the average grain size was 450nm, the samples showing better properties were those sintered at 1000 and 1100 Celsius degrees at a pressure of 173MPa, and 1000 Celsius degrees at 260MPa. The range macroporosity obtained limit with the mesoporosity, nearly 97 per cent of the macropores is between 50 and 150nm radius. The results indicate that the technique is reproducible and the pores range is reasonably small, this will allow to apply the membrane in the separation of certain substances.
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Processos de hidroxilação do óxido de magnésio (MgO): sínter e magnésia cáustica / Process of hydroxylation of magnesium oxide (MgO): sinter and caustic magnesiaArruda, Cezar Carvalho de 19 February 2014 (has links)
A principal limitação do uso de MgO em refratários é a facilidade com que reage com água formando hidróxido de magnésio (Mg(OH)2) que, devido à sua menor densidade, causa tensões destrutivas nesses materiais. Para outras aplicações, no entanto, a reação de hidroxilação do MgO é necessária, como em produção de agentes antichamas, em compósitos poliméricos e na correção de pH de solos. Observações empíricas na literatura demonstraram que diferentes fontes de MgO possuem reatividades e sensibilidades à hidroxilação distintas. Este estudo analisou o impacto de variáveis externas (por exemplo, a liberação de calor que ocorre durante a reação ou o volume das amostras) que ainda não foi completamente compreendido. O impacto auto-catalítico da temperatura reacional e da exotermia da reação foi avaliado. Por meio de medidas de temperatura in situ e de grau de hidroxilação termogravimétrico, também foram estudados os impactos do volume das amostras testadas e da concentração de sólidos nas suspensões, por meio de medidas de temperatura in situ e termogravimetria. Analisou-se também as principais diferenças estruturais entre duas principais fontes de MgO (sínter de MgO e magnésia cáustica): morfologia de partículas, densidade e área superficial específica. Em seguida, os mecanismos de hidroxilação em suspensões aquosas e seus efeitos foram avaliados por meio de testes de hidroxilação seguidos de termogravimetria, difração de raios-X, medidas de condutividade iônica, densidade, área superficial específica e microscopia eletrônica, e relacionado com as características físico-químicas e morfológicas das respectivas fontes de MgO. Pôde-se constatar que diferenças significativas entre a temperatura nominal do meio reacional e no interior da amostra podem afetar a cinética de hidroxilação do material. O volume e a concentração de sólidos variáveis também podem acentuar consideravelmente os efeitos da exotermia e gerar gradientes de hidroxilação. Também se verificou que a morfologia e a quantidade do Mg(OH)2 formado mudam significativamente dependendo do precursor e em função das condições de tempo-temperatura. / The use of MgO in refractories is restrict due to the easy reaction with water forming magnesium hydroxide (Mg(OH)2). Its lower density causes compressive stresses that can crack their structure. On the other hand, for applications such as the production of flame retardant agents for polymer composites and pH correcting of contaminated soil, this reaction is necessary. Empirical observations in the literature have shown that different sources of MgO have district levels of chemical reactiveness. The present study analyzed the main structural differences between the two main sources of MgO (magnesia sinter and caustic magnesia): particle morphology, density and specific surface area. The mechanisms of hydroxylation of these raw materials in aqueous suspensions and their effects were followed by hydroxylation tests, X-ray diffraction, ionic conductivity, density, specific surface area and scanning electron microscopy. They were associated with the physical characteristics morphological, chemical of these MgO sources. The impact of external variables (e.g., heat release during the reaction or the sample volume), that was not yet completely understood, was also evaluated through temperature measurements carried out in situ and hydroxylation degree accessed by thermogravimetry. The effects of samples volume and solid concentration in aqueous suspension were also investigated. The results showed that differences between the ambient temperature and reaction inside sample temperature can affect the kinetics of hydroxylation of the material. The samples volume and solids concentration can also enhance significantly the effects of heat release and generate gradients of hydroxylation. It was also found out that the morphology and the amount of Mg(OH)2 formed can change depending on the precursor and on the time-temperature conditions.
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Atomistic simulation of thermal transport in oxide nanomaterialsYeandel, Stephen January 2015 (has links)
The aim of this work has been to use atomistic computer simulation methods to calculate the thermal conductivity and investigate factors that will modify the behaviour when applied to three different oxide materials: MgO, SiO2 and SrTiO3. These were chosen as they represent distinct classes of materials and are substrates for thermoelectric devices, where one of the primary goals is to tailor the system to reduce the thermal conductivity. Chapter 1 introduces thermoelectric concepts, gives a background of the theory and a review of various important thermoelectric materials. In Chapter 2 an overview of the interatomic interactions is presented along with details on the implementation of these interactions in a simulation of a 3D periodic crystal. Chapter 3 outlines the importance of phonon processes in crystals and several approaches to the calculation of thermal conductivity are presented. MgO results are given in Chapter 4. Both the Green-Kubo and Boltzmann transport equation (BTE) methods of calculating thermal conductivity were used. The effect on thermal conductivity of two different grain boundary systems are then compared and finally extended to MgO nanostructures, thus identifying the role of surfaces and complex nanostructure architectures on thermal conductivity. In Chapter 5 two different materials with the formula unit SiO2 are considered. The two materials are quartz and silicalite which show interesting negative thermal expansion behaviour which may impact upon the thermal transport within the material. Chapter 6 presents results on the promising thermoelectric material STO. Once again the results from both Green-Kubo and BTE calculations are compared. Grain boundaries are also studied and the effect of inter-boundary distance and boundary type on the thermal conductivity is explored. Finally, a nanostructured STO system (assembled nanocubes) with promising thermoelectric applications is studied. Chapter 7 outlines the conclusions made from this work and suggests areas for future study.
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Radiation tolerance of magnetic tunnel junctions with MgO barriersRen, Fanghui 11 September 2014 (has links)
In the next decade, technology trends--smaller dimension, lower voltage, higher operating frequency--introduce new technical considerations and challenges for radiation effects in integrated circuits. Semiconductor based circuits and traditional dynamic random-access memories will malfunction when exposed to extreme environments, such as space and nuclear reactor. The mechanisms for radiation effect are mainly attributed to the radiation-induced charging of the oxide in a CMOS device. Spintronics is an emerging area of nanoscale electronics involving the detection and manipulation of electron spin. The magnetic tunnel junctions (MTJs), based on the intrinsic spin of the electron, can be used as the storage elements in non-volatile magnetoresistive random-access memories (MRAMs). In this effort, we study radiation tolerance of MTJs by exposing the devices in gamma and neutron radiation environment. Theoretical model for the radiation-induced defects is analyzed in this work. Experiments of the MgO-based MTJs under the conditions of pre- and post-radiation are concluded. MTJs were irradiated with gamma ray to a total dose of 10 Mrad. During the neutron irradiation, total epithermal neutron fluence up to 2.9��10�����/cm�� was obtained. The experimental results show that neither the electrical nor the magnetic properties of MTJs are affected by the radiation. / Graduation date: 2013 / Access restricted to OSU community at author's request from Sept. 11, 2012 - Sept. 11, 2014
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Processing And High Temperature Deformation Of Pure And Magnesia Doped AluminaSwaroop, N R Sathya 01 1900 (has links)
Creep resistance is an important design criterion at high temperatures especially when continuous attempts are made to increase the efficiencies by increasing the operating temperatures. Alumina is an important high temperature material and in addition to that it is used in wide variety of applications such as substrates for electronic packaging, spark plugs, envelopes for sodium vapour lamps, cutting tools (when reinforced with silicon carbide) and in artificial joint prostheses.
Studies on creep in alumina. have started as early as 1961. There are differing mechanisms proposed to explain the creep behaviour of alumina in the literature, but until now there is no any unanimous decision as to what the rate controlling mechanism is. Magnesia doped at ppm levels can produce significant changes in the microstructure of alumina, the most important consequence of that being the grain growth inhibition, which renders alumina superplastic. However, in a stoichiometric oxide like alumina, small impurities can create extrinsic defects which would change the diffusivities and creep rates. Therefore the background impurities in alumina should be kept to a minimum, if small dopant effects have to be studied. The present study was undertaken making use of high purity alumina powder and comparing the grain growth and creep properties of pure and magnesia doped alumina, especially since no such investigation was carried out in the recent past with high purity alumina.
Pure alumina was processed by cold compaction followed by cold isostatic pressing (CIP) and pressureless sintering in air at 1773 K for 1 hour. Magnesia doped alumina was prepared by calcining a mixture of alumina and magnesium nitrate at 973 K for 2 hours followed by cold compaction, CIPing and pressureless sintering in air at 1773 K. Both pure and magnesia doped alumina were further annealed at 1873 K for various times to get grain sizes in the ranges of 1-5 μm.
Grain growth kinetics of pure and magnesia doped alumina were studied at 1823 and 1873 K. The parameter Kg which quantifies the mobility of the grain boundary was got. It was found that Kg had decreased in the magnesia doped alumina (in comparison with pure alumina) by a factor of about 3 to 4 which was marginal and insignificant. The grain sizes followed a log normal distribution in both the cases, indicative of normal grain growth.
Creep studies were conducted on pure and magnesia doped alumina in three modes, namely, constant stress, temperature jump and stress jump test. The temperature range used was 1673 to 1773 K and the stress range used was 10 to 100 MPa. The creep parameters were found to be n~1.6, p~3.7 and Q-545 kJ mol"1 for pure alumina and n~l .3, p~3.0 and Q~460 kJ mol-1 for magnesia doped alumina. The creep rates in the case of magnesia doped alumina were found to have increased by a factor of 2 to 3, in comparison with pure alumina. The increase in creep rates were found to be insignificant. The creep data were analyzed and the possibility of the dislocation and interface reaction controlled creep mechanisms were ruled out since they were inconsistent with the data. It was found, from creep parameters and the comparison of theoretical Coble and Nabarro-Herring creep rates with the experimental rates, that Coble creep might be rate controlling. The activation energy values suggested that aluminium ion diffusing along grain boundary might be the rate controlling species. However, when the theoretical creep rates considering various species were compared, the rate controlling species turned out to be oxygen ion diffusing along the grain boundary.
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The design and construction of an experimental MgO cold cathode X-ray tube for use in XRF spectrometry.Damjanovic, Daniel. 23 May 2013 (has links)
An introduction to the fundamental concepts of X-ray physics and X-ray tube design is given.
This discussion also includes a brief description of various X-ray tube types available
commercially for a number of different industrial applications.
The design of a high-energy MgO cold cathode X-ray tube, which is to be used in an X-ray
fluorescence (XRF) spectrometer, is described in detail with emphasis placed on the electron
beam focusing mechanism and the theory of operation as well as the construction of the X-ray
tube MgO cold cathode, which functioned as the electron emitter of the device. A detailed
account is also given of the output characteristics of the X-ray tube power supply, which has a
direct effect on the design requirements and consequently the performance of the X-ray tube.
An investigation into the manufacture of the vacuum envelope with particular attention focused
on the production of reliable metal-to-ceramic seals was performed. A number of tests were
conducted especially with regard to the maximum temperature that such seals may withstand
without becoming permanently damaged. These tests were essential, since high temperature
gradients tend to develop in an X-ray tube during operation, which the metal-to-cerarnic seals of
the tube must be capable of withstanding if damage to the device is to be avoided.
The set-up of the XRF spectrometer in which the completed X-ray tube was tested is discussed, in
which the X-ray current and voltage measuring techniques are described. Furthermore a detailed
account of the operation of the X-ray detector system and the multichannel analyser is given,
which was used to detect and record spectra of the sample elements excited by the primary
radiation of the X-ray tube.
Finally the measured X-ray tube performance characteristics are discussed and compared to the
predicted results. / Thesis (M.Sc.Eng.)-University of Natal, Durban, 2000.
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Preparation and characterization of synthetic mineral surfaces : adsorption and thermal decomposition of tetraethoxysilane on magnesium oxide, molybdenum, and titanium dioxide surfaces /Jurgens-Kowal, Teresa Ann, January 1996 (has links)
Thesis (Ph. D.)--University of Washington, 1996. / Vita. Includes bibliographical references (p. [318]-347).
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Processos de hidroxilação do óxido de magnésio (MgO): sínter e magnésia cáustica / Process of hydroxylation of magnesium oxide (MgO): sinter and caustic magnesiaCezar Carvalho de Arruda 19 February 2014 (has links)
A principal limitação do uso de MgO em refratários é a facilidade com que reage com água formando hidróxido de magnésio (Mg(OH)2) que, devido à sua menor densidade, causa tensões destrutivas nesses materiais. Para outras aplicações, no entanto, a reação de hidroxilação do MgO é necessária, como em produção de agentes antichamas, em compósitos poliméricos e na correção de pH de solos. Observações empíricas na literatura demonstraram que diferentes fontes de MgO possuem reatividades e sensibilidades à hidroxilação distintas. Este estudo analisou o impacto de variáveis externas (por exemplo, a liberação de calor que ocorre durante a reação ou o volume das amostras) que ainda não foi completamente compreendido. O impacto auto-catalítico da temperatura reacional e da exotermia da reação foi avaliado. Por meio de medidas de temperatura in situ e de grau de hidroxilação termogravimétrico, também foram estudados os impactos do volume das amostras testadas e da concentração de sólidos nas suspensões, por meio de medidas de temperatura in situ e termogravimetria. Analisou-se também as principais diferenças estruturais entre duas principais fontes de MgO (sínter de MgO e magnésia cáustica): morfologia de partículas, densidade e área superficial específica. Em seguida, os mecanismos de hidroxilação em suspensões aquosas e seus efeitos foram avaliados por meio de testes de hidroxilação seguidos de termogravimetria, difração de raios-X, medidas de condutividade iônica, densidade, área superficial específica e microscopia eletrônica, e relacionado com as características físico-químicas e morfológicas das respectivas fontes de MgO. Pôde-se constatar que diferenças significativas entre a temperatura nominal do meio reacional e no interior da amostra podem afetar a cinética de hidroxilação do material. O volume e a concentração de sólidos variáveis também podem acentuar consideravelmente os efeitos da exotermia e gerar gradientes de hidroxilação. Também se verificou que a morfologia e a quantidade do Mg(OH)2 formado mudam significativamente dependendo do precursor e em função das condições de tempo-temperatura. / The use of MgO in refractories is restrict due to the easy reaction with water forming magnesium hydroxide (Mg(OH)2). Its lower density causes compressive stresses that can crack their structure. On the other hand, for applications such as the production of flame retardant agents for polymer composites and pH correcting of contaminated soil, this reaction is necessary. Empirical observations in the literature have shown that different sources of MgO have district levels of chemical reactiveness. The present study analyzed the main structural differences between the two main sources of MgO (magnesia sinter and caustic magnesia): particle morphology, density and specific surface area. The mechanisms of hydroxylation of these raw materials in aqueous suspensions and their effects were followed by hydroxylation tests, X-ray diffraction, ionic conductivity, density, specific surface area and scanning electron microscopy. They were associated with the physical characteristics morphological, chemical of these MgO sources. The impact of external variables (e.g., heat release during the reaction or the sample volume), that was not yet completely understood, was also evaluated through temperature measurements carried out in situ and hydroxylation degree accessed by thermogravimetry. The effects of samples volume and solid concentration in aqueous suspension were also investigated. The results showed that differences between the ambient temperature and reaction inside sample temperature can affect the kinetics of hydroxylation of the material. The samples volume and solids concentration can also enhance significantly the effects of heat release and generate gradients of hydroxylation. It was also found out that the morphology and the amount of Mg(OH)2 formed can change depending on the precursor and on the time-temperature conditions.
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