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21	The Kinetic and Mechanism of The Oxygen Reduction Reaction on Pt, Au, Cu, PtCu/C and CuAu/C in Alkaline Media Lin, Xi January 2016 (has links) No description available. Chemistry Oxygen reduction reaction PtCu, Activation energy CuAu
22	Effect of temperature and curing on the early hydration of cementitious materials Siddiqui, Md Sarwar January 1900 (has links) Master of Science / Department of Civil Engineering / Kyle Riding / Concrete is the most widely used construction material. Concrete strength and durability develop from a series of exothermic reactions involving water called hydration. Long-term durability and performance of concrete is very much dependent on the early hydration behavior of cementitious materials. This study examined the effects of curing temperature and access to moisture on the early age reaction rate of cementitious materials, and methods for quantifying these effects. Apparent activation energy (Ea) relates the effects of temperature on the cement hydration reaction. There are various methods and calculation techniques for estimating Ea that result in greatly varying values. Cement paste and mortar are often used to calculate Ea and used later for concrete. Ea values were calculated using cement mortar and paste by isothermal calorimetry and showed excellent correlation. This validates the use of Ea based on cement paste in modeling concrete behavior. Ea values were also calculated by chemical shrinkage and it showed potential for use in calculating Ea. Cementitious materials need free water to be available for hydration to continue. Curing with either waxy curing compounds or ponded water are common practices. The thickness of distilled water, lime-saturated water, and cement pore water used as a curing method affects the rate of hydration. Water-cementitious material ratio (w/cm) and sample depth affect the performance of water curing, with low w/cm being the most significant. Partial replacement of sand by fine lightweight aggregate also improves the hydration of cementitious material much more than conventional water ponding. Curing compounds showed improvements in cement hydration compared to uncured samples. Cementitious material Hydration Apparent activation energy Effect of Curing Effect of temperature Engineering, Civil (0543)
23	The initial phase of the sodium bisulfite pulping of softwood dissolving pulp Deshpande, Raghu January 2015 (has links) The sulfite pulping process is today practised in only a small number of pulp mills around the globe and the number of sulfite mills that use sodium as the base (cation) is less than five. However, due to the increasing interest in the wood based biorefinery concept, the benefits of sulfite pulping and especially the sodium based variety, has recently gained a lot of interest. It was therefore considered to be of high importance to further study the sodium based sulfite process to investigate if its benefits could be better utilized in the future in the production of dissolving pulps. Of specific interest was to investigate how the pulping conditions in the initial part of the cook (≥ 60 % pulp yield) should be performed in the best way. Thus, this thesis is focused on the initial phase of single stage sodium bisulfite cooking of either 100 % spruce or 100 % pine wood chips. The cooking experiments were carried out with either a lab prepared or a mill prepared cooking acid and the temperature and cooking time were varied. Activation energies for different wood components were investigated as well as side reactions concerning the formation of thiosulfate and sulfate. / Single stage sodium bisulfite cooking was carried out on either spruce or pine wood chips to investigate the influence of several process parameters in the initial phase of such a cook i.e. between 100 % and 60 % pulp yield. The cooking experiments were carried out with either a lab prepared or a mill prepared cooking acid and the temperature and time in the initial stage were varied. The influence of dissolved organics and inorganics components in the cooking liquor on the final pulp properties and side reactions were investigated. The impact of temperature and time on the pulp components were analyzed with respect to carbohydrates, lignin, extractives and thiosulfate. Kinetic equations were developed and the activation energies for delignification and carbohydrate dissolution were calculated using the Arrhenius equation. It was found that if using a mill prepared cooking acid, this had a beneficial effect with respect to side reactions, better extractives removal and higher pH stability during the cook, compared to a corresponding cook with a lab prepared cooking acid. Cooking with mill prepared and lab prepared cooking acids showed the same behaviour with respect to delignification and carbohydrate degradation, but the lab acid experiments resulted in a higher thiosulfate formation during the cook. The cellulose yield was not affected at all during the initial phase of the sulfite cook verifying earlier results by other researchers. The temperature had an influence on both the delignification rate and the rate of hemicelluloses removal. The corresponding activation energies were found to increase in the following order; cellulose, xylan, glucomannan and lignin. / <p>Artikel 1: "The Initial Phase of Sodium Bisulfite Pulping of Spruce: Part 1" ingick i avhandlingen som manuskript. Nu publicerad.</p> Activation energy bisulfite pulping cellulose delignification extractives glucomannan hemicelluloses lignin pine spruce thiosulfate total SO2 xylan
24	Photosynthetic acclimation to temperature of four Eucalyptus species and Sequoia sempervirens Oparah, Irene A. January 2012 (has links) The 3-PG physiological/mensurational hybrid model is a useful forest management tool capable of producing accurate growth results across a number of parameterised species. The temperature data used in the model are the average maximum and minimum values for photosynthesis above the compensation point (Landsberg and Sands 2011). There is a minimum temperature below which positive net CO₂ exchange will not occur, a maximum temperature above which it will not occur and an optimum temperature at which it is maximised. These parameters are used in the 3-PG physiological model of forest production. However, a species’ photosynthetic response to short-term variation may differ from one season to another as species acclimate to temperatures over periods of a few weeks. In this study, acclimation responses of four species of eucalypt and Sequoia sempervirens to long-term temperatures were studied over a wide range of short-term temperature changes in order to identify the minimum, optimum and maximum temperatures of CO₂ assimilation for physiological/mensurational hybrid modelling, and also to identify the sites for which the species would be best suited. In order to achieve the aims of this study, a growth chamber experiment was established. Seedlings of four eucalypt species and Sequoia sempervirens were grown at base-line day/night temperatures of 30/16, 22/12 and 10/5ºC in controlled environment chambers for three months and leaf gas exchange measurements were made of the species at seven short-term temperature levels (5, 10, 15, 20, 25, 30 and 35ºC). The optimum and the maximum temperatures for net photosynthesis increased with an increase in base-line temperature for all species. The highest optimum temperature and net photosynthetic rates recorded were in plants grown at 30/16ºC and the lowest were in those grown at 10/5ºC. The maximum rate of net CO₂ assimilation increased with the temperature at which plants were grown partly because of acclimation in key photosynthetic processes in the Calvin cycle. Responses of maximal carboxylation rate (Vcmax) and also the maximal light-driven electron flux (Jmax) to short-term temperature change varied with base-line temperature for all species studied. Net photosynthesis and photosynthetic parameters measured did not vary significantly with effects of nitrogen, phosphorus and their interaction (p = 0.1468). The ratio of Jmax to Vcmax decreased with increasing leaf temperatures for all species (p < 0.001). These results indicate that the species studied will adapt to long-run changes in temperature, and the parameters obtained from these studies can be used for models that simulate the physiology and growth of the species. Photosynthesis acclimation eucalyptus Sequoia sempervirens Jmax Vcmax activation energy deactivation energy
25	Investigation of vanadium-containing oxide systems : CALPHAD and experiments Yang, Yang January 2016 (has links) Fundamental studies on thermodynamic properties of vanadium-containing oxides systems are essential to understand practical vanadium metallurgical process. The CALPHAD technique is here applied to the thermodynamic modelling of the V-O, Ca-V-O and Ti-V-O systems. The compound energy formalism is used for all the solution phases. All optimization processes and calculations are performed using the Thermo-Calc software package. The present work attempts to develop a self-consistent thermodynamic database of all phases in the studied systems. The obtained datasets can be used to calculate thermodynamic properties, stable as well as metastable phase equilibria and driving forces for oxidation etc. Steelmaking slag is an important secondary source for vanadium extraction. The phase relationships and vanadium distribution in the CaO-SiO2-MgO-V2O3-Al2O3 synthetic slags, whose compositions were chosen based on the relevance to the steel producers, are also studied. Phase equilibria in the temperature range of 1773 to 1823 K at oxygen partial pressure of 10-10 bar and 0.21 bar were characterized. An investigation of the volatilization of vanadium oxide was also carried out in the present work. Isothermal evaporation of vanadium pentoxide in the temperature range between 1723 and 1873 K was investigated by Thermogravimetric Analysis under different oxygen partial pressures, viz. oxygen, air or CO2. The Arrhenius activation energy for the evaporation reaction in various atmospheres was calculated from the experimental results. A mathematical model was developed to describe the kinetics of the evaporation process. Evaporation coefficients and enthalpies in various atmospheres were also estimated. The present results may have some implications in recovering vanadium from different vanadium-bearing sources. / <p>QC 20161202</p> activation energy TGA activity
26	O emprego da termogravimetria na determinação da energia de ativação no processo de combustão de óleos combustíveis / Use of thermogravimetric analysis to determine the activation energy in the combustion process of fuels oils Leiva, Cecilia Rocío Morales 24 August 2005 (has links) Neste trabalho, determinou-se a energia de ativação (Ea) no processo de combustão de três óleos combustíveis cedidos pela PetrobrásCenpes e denominados por A, B e C. Empregou-se análise termogravimétrica (TG) utilizando um sistema Shimadzu 51H e, para todas as amostras observaram-se três regiões oxidativas distintas identificadas como, oxidação à baixa temperatura (LTO), depósito de combustível (FD) e oxidação à alta temperatura (HTO). As energias de ativação foram determinadas como uma função do grau de conversão ('alfa') e temperatura na região LTO e utilizando-se dois métodos cinéticos, denominados ASTM E 1641 (Flynn eWall) e Model Free Kinetics de Vyazovkin. Empregaram-se as seguintes razões de aquecimento: 2,5; 5,0; 10,0; 15,0 e 20,0°C por min entre a temperatura ambiente e 600°C. As demais condições experimentais foram: massa da amostra de aproximadamente 20 mg, suporte de amostra de alumínio e gás de arraste ar sintético com vazão de 100 mL/min. Os valores de Ea encontrados foram os mesmos para ambos os métodos cinéticos: 44 ± 7% kJ/mol ('alfa'=0,1 a 0,9) para amostra A. Para a amostra B os valores de Ea foram em média de 48 ± 4% kJ/mol ('alfa'=0,1 a 0,5) e 66 ± 16% kJ/mol ('alfa'=0,5 a 0,9) e, para a amostra C os valores de Ea foram em média de 58 ± 4% kJ/mol ('alfa'=0,1 a 0,5) e 65 ± 5% kJ/mol ('alfa'=0,5 a 0,9). Conclui-se que a Ea pode ser usada como um parâmetro adequado para apontar uma tendência de comportamento e para caracterizar diferentes óleos sob processo de combustão / In this work activation energies (Ea) in the combustion of three fuels oils were determined through thermogravimetry. The oil samples, here named A, B and C were supplied by Petrobras-Cenpes. The thermogravimetric experiments were performed in a Shimadzu TGA-51H analyzer. In all the combustion experiments three distinct oxidation regions were observed, identified as low temperature oxidation (LTO), fuel deposition (FD) and high temperature oxidation (HTO). Activation energies were determined as a function of conversion degree ('alfa') and temperature for LTO region, following two different procedures, namely Model Free Kinetics and ASTM E 1641. Transient experiments were performed from room temperature up to 600°C, at heating rates of 2.5, 5.0, 10.0, 15.0 and 20.0°C for min. Samples of 20.0 ± 0.5 mg and aluminum crucibles were used. The reacting atmosphere was synthetic air, which was continuously blown over the samples, throughout the analyzer furnace, at a volumetric rate of 100 mL/min. The activation energies resulted equal for both considered methods. For oil A, the activation energy resulted 44 ± 7% kJ/mol ('alfa'=0.1 to 0.9). For oil B it resulted in average 48 ± 4% kJ/mol ('alfa'=0.1 to 0.5) and 66 ± 16% kJ/mol ('alfa'=0.5 to 0.9). For oil C the activation energy resulted 58 ± 3% kJ/mol ('alfa'=0.1 to 0.5) e 65 ± 5% kJ/mol ('alfa'=0.5 to 0.9). It is concluded that the oxidation activation energy is a suitable parameter concerning to point out a tendency of behavior and characterizing different oils under combustion process activation energy combustão combustion energia de ativação fuel oil óleo combustível termogravimetria thermogravimetry
27	Influência da temperatura na dinâmica oscilatória de um sistema químico homogêneo aberto / Temperature influence on the oscillatory dynamics of an open homogeneous chemical system Nogueira, Paulo Alberto 15 June 2011 (has links) As reações químicas genericamente referidas como reações de Belousov-Zhabotinsky (BZ) têm sido bastante utilizadas como paradigmas de complexidade em sistemas químicos homogêneos. Apesar dos avanços consideráveis realizados no estudo de tais sistemas, aspectos como o papel do fluxo de reagentes e da temperatura na dinâmica oscilatória ainda são pouco entendidos. O presente trabalho consiste na investigação experimental do efeito destes dois parâmetros em duas variantes da reação de BZ. Após alguns testes iniciais com o sistema bromato/hipofosfito-acetona/manganês-ferroína, a maioria dos experimentos foi feita com o sistema bromato/ácido oxálico-acetona/cério. A evolução temporal do sistema foi estudada a diferentes temperaturas e em condições de batelada e de fluxo por meio do monitoramento simultâneo do potencial de um eletrodo de platina e espectrofotometricamente na região do UV-vis. A discussão foi baseada na energia de ativação em regime oscilatório, Eω. Para o sistema com dois catalisadores não foram observadas oscilações nas condições de fluxo. Para o sistema com cério, em batelada, com Ce4+ é observado que Eω aumenta conforme o sistema evolui para o estado de equilíbrio termodinâmico. Com Ce3+, em batelada, Eω manteve-se praticamente constante e em fluxo, o valor de Eω foi menor do que o valor observado para o sistema em batelada. / The chemical reactions usually referred to as the Belousov-Zhabotinsky (BZ) reactions have been extensively employed as paradigms of complexity in homogeneous chemical systems. In spite of the considerable advance in the study of such systems, aspects such as the role played by the flux of reactants and temperature on the oscillatory dynamics are still poorly understood. The present work consists of the experimental investigation of the effect of these two parameters on two variants of the BZ reaction. After some initial tests with the bromate/hipophosphite-acetone/manganese-ferroin, most of the experiments were carried with the bromate/oxalic acid-acetone/cerium system. The time-evolution of the system was followed at different temperatures and under batch and flow conditions by means of potentiometric and spectrophotometric (UV-vis region) approaches. The discussion was based on the activation energy under oscillatory regime, Eω. For the two-catalyst system, no oscillations were observed under flow conditions. For the cerium-catalyzed system operated in batch, when Ce4+ is used, it is observed that Eω increases as the system evolves to the thermodynamic equilibrium. With Ce3+, the Eω under batch conditions remained virtually constant and in flow, the value of Eω was lower than the value observed for the batch system. Activation energy Belousov-Zhabotinsky Belousov-Zhabotinsky Energia de ativação Flow Fluxo Oscilações Oscillation
28	Indium Nitride Surface Structure, Desorption Kinetics and Thermal Stability Acharya, Ananta R 12 August 2013 (has links) Unique physical properties such as small effective mass, high electron drift velocities, high electron mobility and small band gap energy make InN a candidate for applications in high-speed microelectronic and optoelectronic devices. The aim of this research is to understand the surface properties, desorption kinetics and thermal stability of InN epilayers that affect the growth processes and determine film quality as well as device performance and life time. We have investigated the structural properties, the surface desorption kinetics, and the thermal stability using Auger electron spectroscopy (AES), x-ray diffraction (XRD), Raman spectroscopy, atomic force microscopy (AFM), high resolution electron energy loss spectroscopy (HREELS), and temperature programmed desorption (TPD). Investigations on high pressure chemical vapor deposition (HPCVD)-grown InN samples revealed the presence of tilted crystallites, which were attributed to high group V/III flux ratio and lattice mismatch. A study of the thermal stability of HPCVD-grown InN epilayers revealed that the activation energy for nitrogen desorption was 1.6±0.2 eV, independent of the group V/III flux ratio. Initial investigations on the ternary alloy In0.96Ga0.04N showed single-phase, N-polar epilayers using XRD and HREELS, while a thermal desorption study revealed an activation energy for nitrogen desorption of 1.14 ± 0.06 eV. HREELS investigations of atomic layer epitaxy (ALE)-grown InN revealed vibrational modes assigned to N-N vibrations. The atomic hydrogen cleaned InN surface also exhibited modes assigned to surface N-H without showing In-H species, which indicated N-polar InN. Complete desorption of hydrogen from the InN surface was best described by the first-order desorption kinetics with an activation energy of 0.88 ± 0.06 eV and pre-exponential factor of (1.5 ± 0.5) ×105 s-1. Overall, we have used a number of techniques to characterize the structure, surface bonding configuration, thermal stability and hydrogen desorption kinetics of InN and In0.96Ga0.04N epilayers grown by HPCVD and ALE. High group V/III precursors ratio and lattice mismatch have a crucial influence on the film orientation. The effects of hydrogen on the decomposition add to the wide variation in the activation energy of nitrogen desorption. Presence of surface defects lowers the activation energy for hydrogen desorption from the surface. indium nitride tilted crystallites polarity thermal desorption activation energy
29	Apoferritin Crystallization in relation to Eye Cataract Bartling, Karsten 22 August 2006 (has links) Protein crystallization is significant in both biotechnology and biomedical applications. In biotechnology, crystallization is essential for determining the structure of both native and synthesized therapeutically important proteins. It can also be used as a final purification step and as a stable form for protein storage. With regard to biomedical systems, protein crystallization appears to be involved in the development and manifestation of certain human diseases. In particular, there exists evidence that L-rich ferritin crystals are involved in Hereditary Hyperferritinemia Cataract Syndrome (HHCS). In the current research a microbatch crystallization apparatus has been introduced that enables (1) multiple batch crystallization experiments at various temperatures and solution conditions in parallel and (2) quantitative monitoring of crystal growth without disturbing the progress of an experiment for observation. The primary application of the apparatus is, but not limited to, screening of protein crystallization conditions, although the system can also be used for other macromolecular and small-molecule crystallization experiments. Multiwell microbatch experiments demonstrated the dependence of apoferritin crystal growth kinetics and final crystal size on temperature and cadmium concentration. Although the solubility of apoferritin might be independent of temperature, the results of this study show that the crystal growth kinetics are affected by temperature, profoundly under some conditions. For apoferritin under near physiological conditions the solution thermodynamics in the form of the second virial coefficient have proofed to be a valuable predictor for the crystallization outcome. Furthermore, the significance of the elevated level of some divalent cations in cataractous lenses has been studied both in dilute solutions and under crystallization conditions and cadmium seems to be sole menace in apoferritin condensation. Activation energy for crystallization Cataract Apoferritin Second virial coefficient Crystallization Thermal gradient Light Scattering Microbatch
30	Glass Forming Ability and Relaxation Behavior of Zr Based Metallic Glasses Kamath, Aravind Miyar 2011 May 1900 (has links) Metallic glasses can be considered for many commercial applications because of the higher mechanical strength, corrosion and wear resistance when compared to crystalline materials. To consider them for novel applications, the challenge of preparing metallic glasses from the liquid melt phase and how the properties of metallic glasses change due to relaxation need to be understood better. The glass forming ability (GFA) with variation in composition and inclusion of different alloying elements was studied by using thermal techniques to determine important GFA indicators for Zr-based bulk metallic glasses (BMG). The effect of alloying elements, annealing temperature and annealing time on the thermal and structural relaxation of the BMGs was studied by using an annealing induced relaxation approach. The thermal relaxation was studied by measuring specific heat of the samples using differential scanning calorimeter (DSC) and calculating the enthalpy recovery on reheating in the BMG samples. The structural relaxation was also studied by using extended X-ray absorption fine structure (EXAFS) technique on the as-obtained and relaxed samples. The effects of alloying elements and annealing on electrical resistance were studied by using a two point probe. From the study, it was found that the currently used GFA indicators are inadequate to fully capture and identify the best GFA BMGs. The fragility (beta) of the melt is a new criterion that has been proposed to measure and analyze GFA. The enthalpy relaxation of Zrbased BMGs was found to follow a stretched exponential function, and the parameters obtained showed the BMGs used in the current study are strong glass formers. EXAFS studies showed variations in the structure of BMGs with changes in alloying elements. Furthermore, alloying elements were found to have an effect on the structure of the relaxed BMGs. The resistance of BMGs was found to decrease with relaxation which can be attributed to short range order on annealing. Bulk metallic glass Glass forming ability (GFA) Enthalpy Relaxation Activation Energy EXAFS

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