Study of catalysts for isobutene and alcohols transformation in view of biomass valorization / Valorisation de la biomasse par l’étude de catalyseurs pour la transformation de l’isobutène et d’alcools

Lilic, Aleksandra

09 June 2017

Ce travail de thèse se focalise sur l'impact des propriétés acido-basiques des catalyseurs (quantité et force des sites) dans la production d’acroléine par couplage oxydant d’alcools en phase gazeuse. L'influence du rapport entre site acides et sites basiques des catalyseurs a été étudiée dans la condensation aldolique de l'acétaldéhyde et du formaldéhyde en acroléine, réalisée en conditions oxydantes. Les données et corrélations obtenues ont donné des informations indispensables à l’identification des paramètres qui doivent être modifiés afin d'améliorer la sélectivité en acroléine. La première réaction du procédé implique l'oxydation du méthanol et de l'éthanol respectivement en formaldéhyde et acétaldéhyde sur un catalyseur rédox de type FeMoOx.Ensuite, l'aldolisation croisée des deux aldéhydes et la déshydratation en acroléine sont effectuées sur des catalyseurs acido-basiques.Les alcools impliqués dans ce procédé pouvant dériver de la biomasse, cette nouvelle voie de production d'acroléine présente un intérêt élevé puisqu'elle peut remplacer la production actuelle d'acroléine basée sur des ressources fossiles (aujourd'hui l’acroléine est produite industriellement par oxydation du propylène).Le catalyseur optimal doit présenter des caractéristiques amphotères avec une quantité similaire de sites basiques et acides. Une présence modérée et équilibrée de sites acides et basiques améliore le rendement en acroléine et déplace à plus haute température la production des oxydes de carbone. Parmi tous les catalyseurs étudiés, et grâce à ses propriétés acido-basiques spécifiques, MgO supporté sur silice a été identifié comme étant le meilleur catalyseur pour la condensation aldolique des aldéhydes en acroléine en conditions oxydantes / The present work focuses on the impact of the amount and strength of acidic and/or basic sites on the yield of acrolein produced by alcohols oxidative coupling in gas phase. The influence of acid/base ratio of catalytic sites has been studied in the aldol condensation of acetaldehyde and formaldehyde to acrolein performed in oxidizing conditions. The obtained data and correlations supplied valuable information to understand which parameters have to be modified to improve the acrolein selectivity. The first reaction of the process implies methanol and ethanol oxidation respectively to formaldehyde and acetaldehyde on a FeMoOx redox catalyst. Then the cross-aldolization of the two aldehydes and the dehydration to acrolein is performed on acid/base catalysts. Because the alcohols involved in this process can be bio-sourced, this new route to produce acrolein presents a very high interest, since it can replace the current fossil-based acrolein production (nowadays industrially produced by oxidation of propylene). The optimal catalyst should present amphoteric features with a similar amount of both basic and acidic sites. A moderate and balanced presence of acidic and basic sites improves the acrolein yield and the production of carbon oxides is significantly increased only at high temperature. Among all studied catalysts, MgO supported on silica has been identified as the best catalyst for aldol-condensation of aldehydes to acrolein in oxidizing conditions thanks to a given ratio of basic to acidic sites

Biomasse

Acroléine

Couplage oxydant d’alcools

Calorimétrie d’adsorption

Propriétés acido-basiques

Biomass

Acrolein

Adsorption microcalorimetry

Acid/base properties

541

Chip-Calorimetric Monitoring and Biothermodynamic Analysis of Biofilm Growth and Interactions with Chemical and Biological Agents

Mariana, Frida

21 July 2015

Over the last years, varieties of technologies for biofilm analysis were developed and established. They work on different principles and deliver information about biofilms on different information levels. In this work, chip-calorimetry was applied as an analytical tool that measures heat produced from biofilms. Any change of metabolism in biofilms is reflected by a changed heat flow. The heat, which is the integral of the heat flow vs. time, is quantitatively related to the growth stoichiometry of the biofilm, as described by the Hess’ Law. The heat flow is related to the growth kinetics with the reaction heat as proportionality factor. The results from the calorimetric measurement thus, deliver general information about growth stoichiometry and kinetics. The other interpretation of calorimetric results bases on the assumed proportionality between heat flow and oxygen consumption rate (- 460 kJ/mol ). This ratio is called oxycaloric equivalent. Because in case of aerobic growth the majority of oxygen is consumed in catabolic processes during the electron transport phosphorylation, calorimetry is assumed to provide information about the catabolic side of the metabolism. The newly developed chip-calorimeter applied in this work is much more suitable for biofilm studies compared to conventional microcalorimeters due to the flow-through design of the calorimetric chamber. The measurement of undisturbed growing biofilms and the comparison with conventional biofilm analysis tools (i.e. plate counts, confocal laser scanning microscopy (CLSM), and the determination of intermediates’ concentrations (e.g. ATP)) demonstrate the proper functionality of the calorimetric method and the related cultivation procedure by delivering measurement results in the range of literature values. However, when the biofilms were challenged with antimicrobial agents i.e. antibiotics, bacteriophage, and predatory bacteria, the calorimetric results surprisingly deviated from the reference analyses. By combining the results of the calorimetric and reference analyses, additional information about the antimicrobial effects on biofilms can be acquired. Combination of heat measurement and plate counts, which is one of the most conventional approaches, demonstrated that antimicrobials (especially the bactericidal acting kanamycin) could cause the loss of culturability while the cells were still metabolically active. The measurement of ATP content resulted in values out of the typical range, which indicated that antimicrobial treatments disturbed the cellular ATP regulation and the ATP concentration was no longer linearly correlated to the cell number. ATP measurements are therefore not suitable for antimicrobial susceptibility testing. The comparison of heat profiles with the biovolume determined by quantification of microscopic images shows an elevated cell specific heat production rate after the introduction of some antimicrobials (antibiotics and bacteriophage). In case of antibiotics, this can be explained as a consequence of the bacterial defense mechanisms. Most of the described defense mechanisms against antibiotics need biological energy and therefore drive the electron transport phosphorylation (ETP). In case of biofilm treatments with bacteriophage, the trigger of increasing ETP might be the synthesis of phage proteins, hull material, and genetic information molecules. In aerobic conditions, oxygen is used as terminal electron acceptor. Elevated ETP leads therefore to an increase in oxygen consumption, which correlates to the heat production using oxycaloric equivalent as a factor. These correlations explain the increase of cell specific heat productions as biofilms were challenged by antibiotics and bacteriophage. However, also a decrease of specific heat production was observed (in case of predatory bacteria). Here, the predatory bacteria activity caused various damages in host cells, including the interruption of ETP. With these experiments, chip-calorimetry was demonstrated as a promising complementary tool in biofilm research, which provides deeper insights about metabolic activity and alterations. It benefits from the noninvasive handling and the online, real-time measurement that allow the method to be applied for monitoring purposes. Furthermore, its miniaturized dimension allows easy integration in more complex analytic systems and also reduces experiment costs with minimal media/chemical consumption. This thesis also demonstrates the potential development of chip-calorimetry to be more suitable for routine analyses. The use of superparamagnetic beads as matrix to grow biofilms allows regulated transfer of biofilm samples into and from the measurement chamber. This was an initial step towards automation and higher-throughput analysis. One further outcome of the thesis is based on the highly interesting fact about the elevated heat production rate of the host cells induced by the phage infection observed in the chip- calorimetric experiments. The volume specific detection limit of the chip-calorimeter is lower compared to a commercial microcalorimeter. Thus, the infection effect of phages was additionally measured in microcalorimeter to get better quantitative information about the thermal effect of the infection. The results showed that the immediate heat increase after the addition of phage into the solution of the host cells appeared to be quantitatively related to the infection factor, MOI (Multiplicity of Infection). Unfortunately, microcalorimetric measurements in closed ampoules are often subjected to the oxygen limitation. Thus, this problem of microcalorimetric measurement has been addressed. The combination of experimental results and mathematical modeling showed that the rate of metabolism in the static ampoules is defined by the diffusion rate of oxygen into media. This factor has to be considered while designing biological experiments in closed calorimetric measuring chambers and interpreting the calorimetric results for their biological meaning. Some possible solutions to overcome the oxygen bioavailability problem are e.g. to design the experiments with low biomass, or by using media with elevated density to float the biomass at the interface to air and thus to reduce the diffusion path.

info:eu-repo/classification/ddc/620

ddc:620

Étude des poly(2-alkyl-2-oxazoline)s munis d'extrémités hydrophobes en solution aqueuse et à linterface eau/air

El Hajj Obeid, Rodolphe

January 2009

Thèse numérisée par la Division de la gestion de documents et des archives de l'Université de Montréal.

Poly(2-isopropyl-2-oxazoline)

Poly(2-isopropyl-2-oxazoline)

Poly(2-ethyl-2-oxazoline)

Poly(2-ethyl-2-oxazoline)

Polymères amphiphiles

Amphiphilic polymers

Polymères téléchéliques

Telechelic polymers

Micelles

Micelles

Microcalorimétrie

Microcalorimetry

Diffusion de la lumière

Light scattering

Interface eau/air

Air/water interface

Estudio de las Proteinas Quinasas C clasicas y su interaccion con ligandos y membranas

Torrecillas Sánchez, Alejandro

12 September 2003

La Proteína Quinasa C (PKC) participa en numerosas funciones fisiológicas a través de distintas rutas de señalización celular. Las isoenzimas clásicas están reguladas por diacilglicerol, ésteres de forbol, calcio y fosfolípidos aniónicos. La presencia de insaturaciones en los diacilgliceroles de la membrana modifica la activación de la PKC alfa.Los dominios C2 de PKC clásicas presentan dos tipos de sitios de unión de calcio y enlazan tres cationes de manera similar. La desnaturalización térmica de estos dominios se desplazó hacia mayores temperaturas con concentraciones crecientes de calcio, siendo mayor el efecto en presencia de fosfolípidos aniónicos. La estructura secundaria de los dominios C2 de PKC clásicas así como de la PKC alfa completa mostró una elevada proporción de hoja beta. La adición de fosfolípidos aniónicos y PMA respectivamente provocó un mayor efecto protector frente a la desnaturalización térmica que sólo con calcio. / Protein Kinase C (PKC) plays a key role in several physiological functions through different celullar signalling pathways. The classical isoenzymes are regulated by diacylglycerol, phorbol esters, calcium, and anionic phospholipids.The presence of insaturations in the membrane diacylglycerols modifies the PKC alpha activation.C2 domains of classical PKC have two different binding sites for calcium, and bind three molecules in a similar way. The thermal denaturation of these domains moved to higher temperatures with increasing calcium concentrations, being this effect hingher in the presence of anionic phospholipids. The secondary structure of both C2 domains from classical PKC and PKC alpha showed a high contribution of beta-sheet component. The addition of anionic phospholipids and PMA produced the main protection against thermal denaturation, respectively

protein kinase C

lipid-protein interaction

protein structure and function

difracción de rayos X

microcalorimetría

proteína quinasa C

interacción lípido-proteína

estructura y función de proteínas

Biomembranas

microcalorimetry

X ray diffraction

fluorescence and infrared spectroscopy

Bioquimica y Biologia Molecular

57

577

Organic farming and the impact of fiber-related digestive processes in pigs / Zum Einfluß faserbezogener Verdauungsprozesse bei Schweinen verschiedener genetischer Herkünfte

Meister, Elke

18 November 2004

No description available.

630 Landwirtschaft

Veterinärmedizin

Agricultural Sciences

ökologische landwirtschaft

pflanzliche Zusammensetzung

Schwein

Verdauungsphysiologie

NSP

Faser

Verdaulichkeit

N-Bilanzen

Mikrobielle Aktivität

SCFA

Fermentationsgase

COSITEC

Mikrokalorimetrie

Ussing Kammer

organic farming

nutrient composition

pigs

digestive physiology

NSP

dietary fiber

digestibility

N-balances

microbial activity

SCFA

fermentation gases

COSITEC

microcalorimetry

Ussing chamber

48.61

48.59

YFP 000: Tierernährung

Tierfutter {Tierhaltung}

YA 000: Land- und Forstwirtschaft

YNC 000: Physiologie

Biochemie

Endokrinologie {Tiermedizin}

Étude des poly(2-alkyl-2-oxazoline)s munis d'extrémités hydrophobes en solution aqueuse et à linterface eau/air

El Hajj Obeid, Rodolphe

January 2009

Thèse numérisée par la Division de la gestion de documents et des archives de l'Université de Montréal

Poly(2-isopropyl-2-oxazoline)

Poly(2-isopropyl-2-oxazoline)

Poly(2-ethyl-2-oxazoline)

Poly(2-ethyl-2-oxazoline)

Polymères amphiphiles

Amphiphilic polymers

Polymères téléchéliques

Telechelic polymers

Micelles

Micelles

Microcalorimétrie

Microcalorimetry

Diffusion de la lumière

Light scattering

Interface eau/air

Air/water interface

Synthesis and applications of N-modified mesoporous carbons / Synthèse et applications de carbones mésoporeux modifiés par de l'azote

Cai, Jingxuan

22 January 2015

Les carbones poreux ont été largement utilisés et étudiés ces dernières années. Ce travail de recherche porte sur la préparation de matériaux carbonés mésoporeux modifiés ou non par de l'azote. Tout d'abord, un carbone mésoporeux pur a été synthétisé. Puis des atomes d'azote ont été introduits dans ce carbone mésoporeux par deux méthodes de dopage ("in situ" et "post-synthèse" respectivement). La comparaison des propriétés acido-basiques dans des conditions différentes pour les trois types de matériaux mésoporeux carbonés, avec ou sans diazote, a été faite grâce à des techniques calorimétriques. Ces carbones mésoporeux ont aussi été utilisés dans l'adsorption de polluants, le stockage de l'hydrogène et en tant que supports pour les métaux précieux et l'oxyde de fer en catalyse. Les différentes performances dans ces applications ont été mises en relation avec les différentes propriétés structurelles et surfaciques causées par le dopage au diazote / Porous carbon materials are widely used and studied in recent years. In this work, three kinds of mesoporous carbon materials were prepared. Firstly, cost-effective pure mesoporous carbon was synthesized. Then nitrogen atoms were introduced into the mesoporous carbon by “in situ” and “post” doping methods respectively. The comparisons of the acid-base properties in different conditions of the three kinds of mesoporous carbon materials with or without nitrogen were studied and revealed by different calorimetric techniques. The three kinds of mesoporous carbons were also applied in pollutants adsorption, hydrogen storage and as supports of precious metals and iron oxide in catalysis. The different performances in applications were related to the different structural and surface properties caused by the N-doping

Matériaux de carbone mésoporeux

Dopage à l’azote

Propriétés acido-basiques

Adsorption de polluants

Stockage de l'hydrogène

Hydrogénation du toluène

Effet spillover

Microcalorimétrie d'adsorption

Calorimétrie en phase liquide

Mesoporous carbon materials

Nitrogen doping

Acid-base properties

Pollutants adsorption

Hydrogen storage

Toluene hydrogenation

Spillover effect

Adsorption microcalorimetry

Liquid phase calorimetry

541.395