Estudo da oxidação eletroquímica do ácido fórmico utilizando eletrocatalisadores Pd/C-Sb2O5.SnO2, PdAu/C-Sb2O5.SnO2, PdIr/C-Sb2O5.SnO2 e PdAulr/C-Sb2O5.SnO2 preparados via redução por borohidreto de sódio / Electro-oxidation study of formic acid using Pd/C-Sb2O5•SnO2, PdAu/C-Sb2O5•SnO2, PdIr/C-Sb2O5•SnO2 and PdAuIr/C-Sb2O5•SnO2 electrocatalysts prepared by sodium borohydride reduction

NANDENHA, JÚLIO

11 November 2016

Submitted by Claudinei Pracidelli (cpracide@ipen.br) on 2016-11-11T12:52:46Z No. of bitstreams: 0 / Made available in DSpace on 2016-11-11T12:52:46Z (GMT). No. of bitstreams: 0 / Os eletrocatalisadores Pd/C, Pd/C-15%ATO, PdAu/C-15%ATO (90:10, 70:30 e 50:50), PdIr/C-15%ATO (90:10, 70:30 e 50:50) e PdAuIr/C-15%ATO (90:5:5, 70:20:10 e 50:45:5) foram preparados pelo método de redução por borohidreto de sódio. Esses eletrocatalisadores foram caracterizados por espectroscopia de energia dispersiva de raios X (EDX), difração de raios X (DRX) e microscopia eletrônica de transmissão (MET), enquanto que as atividades eletrocatalíticas para a oxidação eletroquímica do ácido fórmico em meios ácido e alcalino foram investigadas por voltametria cíclica, cronoamperometria e experimentos em células a combustível de ácido fórmico direto (DFAFC) em meios ácido e alcalino a 100 ºC e 60 ºC, respectivamente. Os difratogramas de raios X dos eletrocatalisadores PdAu/C-15%ATO, PdIr/C-15%ATO e PdAuIr/C-15%ATO mostraram a presença de fase de estrutura cúbica de Pd (cfc), ligas de Pd-Au, Pd-Ir e Pd-Au-Ir, fases de carbono e SnO2. As micrografias eletrônicas de transmissão indicaram que as nanopartículas foram bem distribuídas sobre o suporte C-ATO e apresentaram alguns aglomerados. Os estudos eletroquímicos para oxidação de ácido fórmico foram realizados utilizando a técnica de camada fina porosa. Todos os eletrocatalisadores preparados foram testados em células a combustível unitárias alimentadas diretamente por ácido fórmico. Nos estudos comparativos entre os melhores eletrocatalisadores, o eletrocatalisador PdAuIr/C-15%ATO (50:45:5) em meios ácido e alcalino apresentou uma atividade eletrocatalítica superior para a oxidação eletroquímica do ácido fórmico em temperatura ambiente em comparação com o eletrocatalisador Pd/C-15%ATO e os outros eletrocatalisadores binários e ternários preparados. Os experimentos em uma DFAFC unitária ácida e alcalina, também, indicaram que o eletrocatalisador PdAuIr/C-15%ATO (90:5:5) apresentou melhor desempenho para oxidação eletroquímica do ácido fórmico a 100 ºC (meio ácido) e a 60 ºC (meio alcalino), respectivamente, em comparação com os demais eletrocatalisadores sintetizados. Esses resultados indicaram que a adição de Au e Ir ao Pd favorece a oxidação eletroquímica do ácido fórmico, esse efeito pode ser atribuído ao mecanismo bifuncional (a presença de ATO (Sb2O5·SnO2), óxidos de Au e Ir) associados ao efeito eletrônico (ligas de Pd-Au-Ir (cfc)). / Tese (Doutorado em Tecnologia Nuclear) / IPEN/T / Instituto de Pesquisas Energeticas e Nucleares - IPEN-CNEN/SP

electrochemistry

electrolytic cells

electrolysis

proton exchange membrane fuel cells

formic acid

electrocatalysts

electronic circuits

reduction

oxidation

sodium hydroxides

borohydrides

x-ray diffraction

fluorescence spectroscopy

transmission electron microscopy

chemical radiation effects

chemical physics

High resolution FTIR spectroscopy using a femto-OPO laser source and cavity enhanced absorption

Golebiowski, Dariusz

27 November 2015

Dans cette thèse, nous améliorons et utilisons le montage expérimental développé au laboratoire nommé femto/OPO-FT-CEAS. Ce montage combine une source laser femto/OPO, une cavité optique haute finesse et un interféromètre à transformée de Fourier. Il permet d'enregistrer des spectres sur un intervalle de 150 cm-1, avec un coefficient d'absorption minimal de 3x10-9 cm-1, à une résolution de 2x10-2 cm-1 et un temps d’acquisition de 2 heures. Un chemin d'absorption de 20 km a été obtenu dans une cellule de 145 cm. Différents miroirs à hauts indices de réflexion permettent d'accéder à deux gamme spectrales dans le domaine de l'infrarouge proche :6200-6700 cm-1 et 7700-8300 cm-1.Le montage femto/OPO-FT-CEAS a été utilisé afin d'enregistrer des spectres à température ambiante. La molécule OCS a été étudiée dans les gammes spectrales de 6200 à 6700 cm-1 et 7700 à 8300 cm-1. Les nouvelles données rovibrationnelles ont été intégrées au modèle global développé par le Prof. Fayt de l'université catholique de Louvain. Un échantillon de CO2 enrichi en oxygène 17 a également été étudié dans la gamme spectrale de 7700 à 8300 cm-1. Les données ont été traitées avec l'aide du Dr. Lyulin l'institut d'optique atmosphérique de Tomsk, Russie.Le montage femto/OPO-FT-CEAS a également été modifié pour enregistrer des spectres de molécules refroidies au sein d'un jet supersonique. Les molécules de N2O, C2H4 et H12C13CH en abondance isotopique naturelle ont été étudiées. Le montage permet de refroidir les molécules étudiées jusqu'à 10 K et un coefficient de 5x10-8 cm-1 a été obtenu. Ce montage a également permis d'enregistrer des spectres CEAS et CRDS de NH3 à des températures de 17 et 14 K respectivement. L'analyse des spectres aété réalisée avec l'aide des Profs. Fusina et Di Lonardo de l'Université de Bologne, Italie.Une cellule de 145 cm pouvant être refroidie à l'aide de réfrigérants liquides a également été développée en vue de remplacer une cellule à température ambiante de 77 cm utilisée dans le montage femto/OPO-FT-CEAS.Enfin, les montages FANTASIO+ et femto/OPO-FT-CEAS ont été utilisés afin afin d'enregistrer des spectres de HCOOH à température ambiante et à 10 K. Les données ont été traitées avec l'aide du Dr. Perrin de l'Université Paris-Créteil, France. / Doctorat en Sciences / info:eu-repo/semantics/nonPublished

Chimie quantique

Chimie

Chimie-Physique

Spectroscopie

Infrarouge

Spectroscopie laser

Cavité optique

Cavity enhanced absoprtion spectoscopie

CEAS

Cavity ting-down spectroscopy

CRDS

Spectroscopy

infrared

global model

isotopomer

Carbonyl sulfide

Carbon dioxide

Ammonia

Formic Acid

Études électrochimiques des nanoparticules d'or : corrélation structure/activité / Electrochemical studies of gold nanoparticles : structure/activity correlation

Hebié, Seydou

18 November 2013

Les propriétés inattendues des nanoparticules d'or font que le contrôle de leur taille, de leur forme et/ou de leur morphologie devient essentiel pour une application ciblée. Des formes variées de nanoparticules en solution colloïdale ont été synthétisées. L'analyse de ces solutions par spectroscopie UV-Visible montre que les nanoparticules anisotropes ont deux bandes plasmoniques. Aussi, le potentiel zêta mesuré révèle que les solutions sont stables dans les conditions d'étude. La caractérisation par la microscopie électronique en transmission a permis d'observer que leur surface présente différentes orientations cristallographiques. Le dépôt sous potentiel du plomb par voltammétrie cyclique a révélé les sites cristallographiques à la surface de ces nanomatériaux. Ces matériaux présentent des proportions de surface orientée (111), (110) et (100) et de défauts cristallins en accord avec les résultats de microscopie. L'étude électrochimique dans l'électrolyte support montre que la formation des oxydes sur ces nanomatériaux dépend de leur structure. La cinétique de croissance des couches d’oxyde sur les nanobâtonnets d’or dépend fortement du potentiel, du temps de polarisation et de la température. Des différentes formes structurales des nanomatériaux d'or synthétisés et en présence de molécules modèles telles que le glucose et l'acide formique, les nanosphères présentent l'activité la plus forte pour l'oxydation du glucose ; tous les nanomatériaux sont moins actifs pour l'oxydation de l'acide formique. Les analyses par FTIR in situ mettent en évidence la gluconolactone comme intermédiaire de cette réaction et la forte influence de la structure de surface. / Due to the unusual properties of gold nanoparticles, the control of their size, their shape and/or their morphology for a well-targeted application becomes essential. Various shape controlled particles in colloidal solutions were synthesized. The analysis of such solution by UV-visible spectroscopy shows that the anisotropic particles exhibit two surface plasmon resonance bands. In addition, the zeta potential measurements reveal that such solutions are stable in the experimental conditions. It is clearly observed by the transmission electron microscopy characterization of these nanomaterials that their surface has different crystallographic orientations. The under potential deposition (upd) of lead by cyclic voltammetry revealed the surface crystallographic sites which present different ratio of orientated surface (111), (110), (100) and defaults confirming the microscopy results. The cyclic voltammetry in supporting electrolyte shows that the oxides formation on these nanomaterials depends strongly on their structure. On gold nanorods, an extensive study of the kinetic of the oxide layers growth shows that this process is affected by the polarization potential and time as well as temperature. The nanospheres exhibited high activity toward the glucose oxidation, while all the synthesized nanomaterials presented low activity toward the formic acid oxidation. Gluconolactone appears as the main intermediate species during the oxidation of glucose which is a surface structure dependent process.

Nanoparticules d’or

Taille

Forme

Structure de surface

Dépôt en sous potentiel (upd)

Croissance des oxydes

Glucose

Acide formique

Oxydation

Électrocatalyse

Gold nanoparticles

Size

Shape

Surface structure

Under potential deposition (upd)

Oxides growth

Glucose

Formic acid

Oxidation

Electrocatalysis

541.3

Mechanistic Insights Into Small Molecule (Amine-Boranes, Hydrogen, Methane, Formic Acid Carbon dioxide) Activation Using Electrophilic Ru(II)-Complexes

Kumar, Rahul

January 2016

Current fossil fuels (Coal and Petroleum) based economy is not sustainable in the long run because of its dwindling resources, and increasing concerns of climate change due to excessive carbon dioxide (CO2) emission. To mitigate CO2 emission and climate change, scientists across the world have been looking for clean and sustainable energy sources. Among them hydrogen gas (H2) could be more promising because it is the most clean fuel and can be produced from cheap source (water) which is renewable and abundant. Nevertheless, the bottleneck for hydrogen economy is lying in the cost of hydrogen production from water. Still there are no any efficient systems developed which can deliver hydrogen from water in economically viable way. Meanwhile, recent research on old molecule ammonia-borane (H3N•BH3, AB) as hydrogen source has increased the hope towards the hydrogen economy, however, catalytic recycling (or efficient regeneration) of AB from the dehydrogenated product polyborazylene (PB or BNHx) is the biggest hurdle which prevents use of AB as practical hydrogen storage material. Therefore, it is imperative to understand the dehydrogenation pathways of ammonia-borane (or related amine-boranes) which lead to polymeric or oligomeric product(s). On the other hand, methane (CH4) is abundant (mostly untamed) but cleaner fuel than its higher hydrocarbon analogs. To develop highly efficient catalytic systems to transform CH4 into methanol (gas to liquid) is of paramount importance in the field of catalysis and it could revolutionize the petrochemical industry. Therefore, to activate CH4, it is crucial to understand its binding interaction with metal center of a molecular catalyst under homogenous condition. However, these interactions are too weak and hence σ–methane complexes are very elusive. In this context, σ-H2 and σ-borane complexes bear some similarities in σ-bond coordination (and four coordinated boranes are isoelectronic with methane) could be considered as good models to study σ-methane complexes. Studying the H−H and B−H bond activation in H2 and amine-boranes, respectively, would provide fundamental insights into methane activation and its subsequent functionalization. Moreover, the proposed methanol economy by Nobel laureate George Olah seems more promising because methanol can be produced from CH4 (CO2 as well). This in turn will gradually reduce the amount of two powerful greenhouse gases from the earth’s atmosphere. Thus, efficient and economic production of methanol from CH4 and CO2 is one of most challenging problems of today in the field of catalysis and regarded as the holy grails. Furthermore, very recently formic acid (HCOOH) is envisaged as a promising reversible hydrogen storage material because it releases H2 and CO2 in the presence of a suitable and efficient catalyst or vice versa under ambient conditions. Objective of the research work: Taking the account of the above facts, the research work in this thesis is mostly confined to utilize electrophilic Ru(II)-complexes for activation of small molecules such as ammonia-borane (H3N•BH3) [and related amine-borane (Me2HN•BH3)], hydrogen (H2), methane (CH4), formic acid (HCOOH) and carbon dioxide (CO2) and investigation of their mechanistic pathways using NMR spectroscopy under homogeneous conditions. Though these molecules are small, they have huge impacts on chemical industries (energy sector and chemical synthesis: drugs/natural products) and environment [CO2 and CH4 are potent green house gases] as well. However, they are relatively inert molecules, especially CH4 and CO2, and impose very tough challenges to activate and functionalize them into useful products under ambient conditions. The partial oxidation of the strong C−H bond in CH4 for its transformation into methanol under relatively mild condition using an organometallic catalyst is considered as a holy grail in the field of catalysis which is mentioned earlier. More importantly, to develop better and highly efficient homogeneous catalytic systems for the activation of these molecules, it is imperative to understand the mechanistic pathways using well defined homogeneous metal complexes. Thus, an understanding of the interaction of these inert molecules with metal center is obligatory. In this context, discovery of a σ-complex of H2 gave remarkable insights into H−H bond activation pathways and its implications in catalytic hydrogenation reactions. Subsequently, σ-borane complexes of amine-boranes were discovered and found to be relatively more stable because of stronger M−H−B interaction and hence act as good models to study the M−H−C interaction of elusive σ-methane complex. On the other hand, HCOOH, a promising hydrogen storage material and its efficient catalytic dehydrogenation/decarboxylation and CO2 hydrogenation back to HCOOH using well defined homogeneous catalysts could lead to a sustainable energy cycle. Therefore, it is quite significant to understand the mechanistic pathways of formic acid dehydrogenation/decarboxylation and carbon dioxide reduction to formic acid for the development of next generation efficient catalysts. Chapter highlights: Keeping all these in view, we carried out thorough studies on the activation of these small molecules by electrophilic Ru(II)-complexes. This thesis provides useful insights and perspective on the detailed investigation of mechanistic pathways for the activation of small molecules such as H3N•BH3 [and Me2HN•BH3], H2, CH4, HCOOH and CO2 using electrophilic Ru(II)-complexes under homogeneous conditions using NMR spectroscopy. In Chapter 1 we provide brief overview of small molecule activation using organometallic complexes. This chapter presents pertinent and latest results from literature on the significance of small molecule activation. Although there are several small molecules which need our attention, however, we have focused mainly on H3N•BH3 [and Me2HN•BH3], H2, CH4, HCOOH and CO2. In Chapter 2, we present detailed investigation of mechanistic pathways of B−H bond activation of H3N•BH3 and Me2HN•BH3 using electrophilic [RuCl(dppe)2][OTf] complex using NMR spectroscopy as a model for methane activation. In these reactions, using variable temperature (VT) 1H, 31P{1H} and 11B NMR spectroscopy we detected several intermediates en route to the final products at room temperature including a σ-borane complex. On the basis of elaborative studies using NMR spectroscopy, we have established the complete mechanistic pathways for dehydrogenation of H3N•BH3/Me2HN•BH3 and formation of B−H bond activated/cleaved products along with several Ru-hydride and Ru-(dihydrogen) complexes. Keeping the B−H bond activation of amine-boranes in view as a model for methane activation, we attempted to activate methane using [RuCl(dppe)2][OTf] complex. In addition, [Ru(OTf)(dppe)2][OTf] complex having better electrophilicity than [RuCl(dppe)2][OTf], was synthesized and characterized. The [Ru(OTf)(dppe)2][OTf] complex has highly labile triflate bound to Ru-metal and therefore its reactivity studies toward H2 and CH4 were carried out where H2 activation was successfully achieved, however, no any spectroscopic evidence was found for C−H bond activation of CH4. The Chapter 3 describes the synthesis and characterization of several Ru-Me complexes such as trans-[Ru(Me)Cl(dppe)2], [Ru(Me)(dppe)2][OTf], trans-[Ru(Me)(L)(dppe)2][OTf] (L = CH3CN, tBuNC, tBuCN, H2) with an aim to trap corresponding σ-methane intermediate at low temperature. However, interestingly, we observed spontaneous but gradual methane elimination and orthometalation of [Ru(Me)(dppe)2][OTf] complex at room temperature. We thoroughly investigated mechanistic details of methane elimination and orthometalation of [Ru(Me)(dppe)2][OTf] using VT NMR spectroscopy, NOESY and DFT calculations. Furthermore, H2 activation was confirmed unambiguously by [Ru(Me)(dppe)2][OTf] and Ru-orthometalated complexes using NMR spectroscopy under ambient conditions. An effort was also made to activate methane using Ruorthometalated complex in pressurized condition of methane in a pressure stable NMR tube. Moreover, preliminary studies on protonation reaction of [Ru(Me)(dppe)2][OTf] using VT NMR spectroscopy to trap σ-methane at low temperature was carried out which provided us some useful information on dynamics between proton and Ru-Me species. The Chapter 4 provides useful insights into the mechanistic pathways of dehydrogenation/decarboxylation of formic acid using [RuCl(dppe)2][OTf]. Catalytic dehydrogenation of HCOOH using [RuCl(dppe)2][OTf] was observed in presence of Hunig base (proton sponge). In addition, a complex [Ru(CF3COO)(dppe)2][OTf] was synthesized and characterized using NMR spectroscopy, and found to readily dehydrogenate HCOOH. Moreover, preliminary results on transfer hydrogenation of CO2 into formamide using [RuCl(dppe)2][OTf] as a precatalyst and tert-butyl amine-borane (tBuH2N•BH3) as secondary hydrogen source was confirmed using 13C NMR spectroscopy. The mechanisms were proposed for HCOOH dehydrogenation and transfer hydrogenation of CO2 based on our NMR spectroscopic studies. Furthermore, a few test reactions of transfer hydrogenation of selected alkenes such as cyclooctene, acrylonitrile, 1-hexene using [RuCl(dppe)2][OTf] as pre-catalyst and tert-butyl amine-borane (tBuH2N•BH3) as secondary hydrogen source showed quantitative conversion to hydrogenated products.

Electrophilic Ruthenium Complexes

Small Molecules Activation

Amine Borane Activation

Organometallic Complexes

Methane Activation

Formic Acid Activation

Carbon Dioxide Activation

Hydrogen Activation

NMR Spectroscopy

Electrophilic Ru(II)-Complexes

Inorganic Chemistry

Tropospheric ozone and photochemical processing of hydrocarbons : laboratory based kinetic and product studies

Leather, Kimberley

January 2012

Laboratory based temperature-dependent kinetics and product yields for alkene ozonolysis and the reaction of CH3O2 with ClO and BrO have been measured via chamber studies and a turbulent flow tube coupled to CIMS (Chemical Ionisation Mass Spectrometry). In order to gain a better understanding of the fate of the products formed during hydrocarbon oxidation and their subsequent impact on the ozone budget (and so the oxidising capacity of the atmosphere) it is imperative to know the rate at which these reactions proceed and to identify their product yields. As tropospheric temperature varies, Arrhenius parameters were determined during the ozonolysis of selected alkenes. The temperature dependent kinetic database was extended and the activation energies for the ozonolysis of selected alkenes were correlated with an existing SAR (Structure Activity Relationship). Given the myriad organic species in the atmosphere, SARs are useful tools for the prediction of rate coefficients. Inclusion of Arrhenius parameters into the SAR allows for prediction over a range of temperatures, improving the conditions reflected in models. Achieving mass balance for alkene ozonolysis has proven to be a difficult challenge considering the numerous pathways of the Criegee Intermediate (CI). The product yield of formic acid – an organic acid with significant atmospheric implications which is under predicted by models – was determined as a function of relative humidity during ethene ozonolysis. This reaction exhibited a strong water dependence which lead to the prediction of the reaction rate of the CI with water which ranges between 1 × 10-12 – 1 × 10-15 cm3 molecule-1 s-1 and will therefore dominate its loss with respect to bimolecular processes in the atmosphere. Peroxy radicals, strongly influence the total oxidising capacity of the troposphere. The reaction of peroxy radicals with halogen oxides is recognised to be responsible for considerable ozone depletion in the atmosphere, exacerbated by reactive halogens (X, XO) taking part in catalytic cycles. Arrhenius parameters were determined for ClO + CH3O2 and BrO + CH3O2. Temperature is an important parameter affecting rate, exemplified here as the reaction involving ClO exhibited a positive temperature dependence whereas for BrO a negative temperature dependence was evident. As a consequence, the impact of ClO + CH3O2 with respect to ozone loss is diminished. Global modelling predicts a reduction in ozone loss by a factor of around 1.5 and implicates regions such as clean marine environments rather than the polar stratosphere. Conversely, a more pronounced temperature dependence for the reaction of BrO with CH3O2 placed particular importance on lower stratospheric chemistry where the modelled CH3O2 oxidation is doubled. The main products for this reaction were identified to be HOBr and CH2O2. The decomposition of CH2O2 could enhance HOx in the lower and middle stratosphere and contribute to a significant source of HOx in the upper troposphere. Bimolecular reaction of CH2O2 with water could also provide a none negligible source HC(O)OH in the upper troposphere. Alkenes and peroxy radicals undergo chemical processing in the atmosphere whilst acting as a source and sink of ozone and thus can impose detrimental effects on the biosphere, climate and air quality of the Earth.

551.51

Application d’une stratégie de lutte intégrée contre le parasite Varroa destructor dans les colonies d’abeilles mellifères du Québec

Giovenazzo, Pierre

04 1900

Le parasite Varroa destructor provoque depuis plus de 30 ans la perte de nombreuses colonies à travers le monde. L’utilisation d’acaricides de synthèse s’est avérée inefficace au Canada et ailleurs dans le monde à la suite de la sélection de varroas résistants. Dans ce contexte, il est devenu impératif de trouver de nouveaux moyens pour contrôler cette peste apicole. Ce travail original de recherche a pour but de déterminer les paramètres fondamentaux d’une lutte intégrée contre la varroase fondée sur l’utilisation périodique de différents pesticides organiques (l’acide oxalique, l’acide formique et le thymol) associée à des seuils d’interventions. Les seuils d’intervention ont été déterminés à l’aide de régressions linéaires entre les taux de parasitisme par V. destructor et la formance zootechnique des colonies d’abeilles mellifères (production de miel et force des colonies). Un total de 154 colonies d’abeilles du Centre de recherche en sciences animales de Deschambault (CRSAD) ont été suivies de septembre 2005 à septembre 2006. Les seuils calculés et proposés à la suite de cette recherche sont de 2 varroas par jour (chute naturelle) au début mai, 10 varroas par jour à la fin juillet et de 9 varroas par jour au début septembre. L’efficacité des traitements organiques avec l’acide oxalique (AO), l’acide formique (AF) et le thymol a été vérifiée en mai (avant la première miellée) en juillet (entre deux miellées), en septembre (après la miellée et pendant le nourrissage des colonies) et en novembre (avant l’hivernage). L’acide oxalique a été appliqué en utilisant la méthode d’égouttement (4% d’AO p/v dans un sirop de sucrose 1 :1 p/v). L’acide formique a été appliquée sous forme de MiteAwayII™ (tampon commercial imbibé d’AF 65% v/v placé sur le dessus des cadres à couvain), Mitewipe (tampons Dri-Loc™ 10/15cm imbibés de 35 mL d’AF 65% v/v placés sur le dessus des cadres à couvain) ou Flash (AF 65% coulé directement sur le plateau inférieur d’une colonie, 2 mL par cadre avec abeilles). Le thymol a été appliqué sous forme d’Apiguard™ (gélose contenant 25% de thymol p/v placée sur le dessus des cadres à couvain). Les essais d’efficacité ont été réalisés de 2006 à 2008 sur un total de 170 colonies (98 appartenant au CRSAD et 72 appartenant au privé). Les résultats montrent que les traitements de printemps testés ont une faible efficacité pour le contrôle des varroas qui sont en pleine croissance durant cette période. Un traitement avec l’AF à la mi-été permet de réduire les taux de parasites sous le seuil en septembre mais il y a risque de contaminer la récolte de miel avec des résidus d’AF. Les traitements en septembre avec le MiteAwayII™ suivis par un traitement à l’acide oxalique en novembre (5 mL par égouttement entre chaque cadre avec abeilles, 4% d’AO p/v dans un sirop de sucrose 1 :1 p/v) sont les plus efficaces : ils réduisent les niveaux de varroase sous le seuil de 2 varroas par jour au printemps. Nos résultats montrent également que les traitements réalisés tôt en septembre sont plus efficaces et produisent des colonies plus fortes au printemps comparativement à un traitement réalisé un mois plus tard en octobre. En conclusion, ce travail de recherche démontre qu’il est possible de contenir le développement de la varroase dans les ruchers au Québec en utilisant une méthode de lutte intégrée basée sur une combinaison d’applications d’acaricides organiques associée à des seuils d’intervention. / For nearly 30 years, Varroa destructor has been responsible for the loss of many honey bee colonies around the world. The continued use of synthetic acaricides has resulted in their reduced efficacy against this pest in Canada and in other countries because of the selection of resistant mite populations. With this situation still present, it has become of utmost importance to develop efficient methods to control this apicultural pest. The major goal of this original work is to determine the fundamental parameters underlying the use of an integrated pest management (IPM) strategy against the varroa mite. The IPM strategy developed in this research is based on the periodic use of organic pesticides (oxalic acid, formic acid and thymol) and treatment threshold. Treatment thresholds were determined from linear regressions between the varroa mite levels and the zootechnical performances (honey production and colony strength) of honey bee colonies. A total of 154 honey bee colonies from the livestock of the “Centre de recherche en sciences animales de Deschambault” (CRSAD) were monitored from September 2005 to September 2006. Based on our findings, we propose economic treatment thresholds for three periods in the year: early May, late July and early September that are respectively 2, 10 and 9 varroa mites per day. Efficacy of the various organic treatments: formic acid (FA), oxalic acid (OA) and thymol was evaluated in May (before the first honey flow), in July between two honey flows, in September (after the honey flow and before the fall feeding of colonies) and in November (before wintering). OA was applied using the trickling method (4% OA w/v in a sucrose syrup 1:1 w/v). FA was applied using MiteAwayII™ (pads imbedded with FA 65% v/v placed on top of brood frames), Mitewipe (Dri-Loc™ pads 10/15cm imbedded with 35 mL FA 65% v/v placed on top of brood frames), Flash (FA 65% poured directly on the bottom board of colonies, 2 mL per frame with bees). Thymol was applied using Apiguard™ (gel with 25% de thymol w/v placed on top of the brood frames). Efficacy trials were realised from 2006 to 2008 on a total of 170 colonies (98 from the CRSAD and 72 owned by a commercial beekeeper). Results show that treatments applied in spring give low efficacy on reducing varroa mite populations that are in full growth at this time because of large amounts of brood available for mite reproduction. Application of a FA treatment in mid-summer offers the opportunity to reduce mite populations at the 11 mites per day September threshold but FA summer application is accompanied by a risk of incorporating residues in the harvested honey. Application of MiteAwayII™ in September followed by an oxalic acid treatment in November (trickling method 4% OA w/v in a sucrose syrup 1 :1 w/v, 5 mL between frames with bees) gave the best efficacy results: varroa mite levels are reduced below the 2 mites per day spring threshold. Our results also show that an early September management strategy of colonies for winter preparation (varroa treatment and fall feeding) gives greater varroa control, higher colony winter survival and stronger colonies in spring when compared to a later treatment in October. In conclusion, this work shows that varroa mite control in honey bee colonies in Québec is possible by using an integrated pest management strategy based on the application of a combination of organic acaricides in association with treatment thresholds.

Varroa destructor

Apis mellifera

Seuil d’intervention

Pesticide organique

Acide formique

Acide oxalique

Thymol

Treatment thresholds

Organic pesticide

Formic acid

Oxalic acid

Development of a GC Method for the Quantification of Short Chain Carboxylic Acids in Aqueous Solution

Åkervall, Anton

January 2020

Petroleum powered vehicles emit volatile organic compounds (VOCs) through combustion that contributes to the pollution of the environment. A technique in the 1970s was developed to decrease these emissions, especially for nitrogen oxides (NOx) and sulphuric oxides (SOx) which is called exhaust gas recirculation (EGR). The technique works by recirculating a portion of the combusted gas back into the engine, this limits the NOx and SOx emissions because of lower temperatures and less available oxygen. The problems that follow these effects is the formation and condensation of acids that corrode the material of the EGR system, which are created by many different reactions. It is of importance to understand how the compounds in the EGR system behaves through analysis of authentic and simulated condensates, which is why a quantitative method for these compounds are of interest. The aim of the project was to develop a simple quantitative analysis method for formic acid, acetic acid, and lactic acid in aqueous solution, which was done at Gränges Sweden AB. The technique used for detection and quantification was gas chromatography (GC) coupled to a flame ionization detector (FID) and a water compatible polyethylene glycol (PEG) column. Fractional factorial design (FFD) was used for determination of adequate operating parameters of the GC method and the sample preparation. Sample preparation only required filtration and pH adjustment prior to direct aqueous injection (DAI) to the chromatographic instrument. Detection of the analytes was very difficult because of non-compatibility with the FID, and quantification of asymmetric peak shapes made this problem worse, omitting lactic acid from further analysis. Limit of detection (LOD) and limit of quantification (LOQ) was 490 and 1640 ppm for formic acid and 120 and 400 ppm for acetic acid, with an injection volume of 0.3 μL and split ratio 10:1. Limits were too high for every EGR sample leaving no peaks detected for the sample preparation used. Further development should be done with complementary techniques and sample reprocessing in order to quantify the compounds.

DAI-GC-FID

Direct Aqueous Injection

Gas Chromatography

Flame Ionization Detector

SCFA

Short Chain Fatty Acids

Formic Acid

Acetic Acid

Lactic Acid

EGR

Exhaust Gas Recirculation

CAC

Charged Air Cooler

FFD

Fractional Factorial Design

Analytical Chemistry

Analytisk kemi

Transformations of Energy-Related Small Molecules at Dinuclear Complexes

Lücken, Jana

02 November 2021

No description available.

540

water oxidation

oxygen activation

formic acid decarboxylation

ruthenium

cobalt

copper

dinuclear complexes

copper hydride

transition metal complexes

coordination chemistry

small molecule activation

catalysis

WOC

small molecule transformation

SMM

magnetism

Chemie  (PPN62138352X)

Die pleiotrope Maturation der sauerstofftoleranten [NiFe]-Hydrogenasen aus Ralstonia eutropha

Bürstel, Ingmar

06 May 2013

Hydrogenasen sind komplexe Enzyme, die die reversible Oxidation von molekularem Wasserstoff zu Protonen und Elektronen katalysieren. Diese Enzyme erlauben ihrem Wirtsorganismus das Wachstum unter chemolithoautotrophen Bedingungen. Der Modellorganismus Ralstonia eutropha besitzt drei gut charakterisierte Hydrogenasen der [NiFe]-Klasse, die sich durch ihre Sauerstofftoleranz auszeichnen. Ihr aktives Zentrum besteht aus einer komplexen prosthetischen Gruppe, welche aus einem Nickel- und einem Eisenatom besteht. Letzteres koordiniert drei diatomare Liganden, zwei Cyanide und ein CO. Die Synthese der gesamten Ni(SR)2(µ-SR)2Fe(CN)2(CO)-Gruppe ist ein komplexer Prozess. Die sogenannte Maturation benötigt wenigstens sechs akzessorische Proteine, die sogenannten Hyp-Proteine. Das umfassende Verständnis dieser Maturationsprozesse ermöglicht eine Vielzahl von biotechnologischen Anwendungen. Die vorliegende Arbeit untersucht die Maturation unter verschiedenen Gesichtspunkten. Zentrale, offene Fragen sind die Herkunft des Carbonylliganden sowie die Prozesse, die zur Ligandierung des katalytischen Eisens führen. Dazu wurden molekularbiologische, biochemische und spektroskopische Methoden in Verbindung mit Isotopenmarkierung eingesetzt. Unter anderem konnte dabei gezeigt werden, dass das katalytische Eisen alle seine Liganden bereits im HypCD-Komplex, dem zentralen Element der Maturation, erhält. Ferner konnte in dieser Arbeit, erstmalig für [NiFe]-Hydrogenasen, eine konkrete Biosynthese des seltenen und toxischen diatomaren CO-Liganden beschrieben werden. Ausgehend vom Alpha-Kohlenstoff von Glycin wird der Tetrahydrofolat (THF)-abhängige C1-Metabolismus mit C1-Einheiten versorgt. Durch die enzymatische Aktivität von HypX wird die Formylgruppe von N10-Formyl-THF zu CO umgesetzt. / Hydrogenases are complex enzymes that catalyze the reversible oxidation of molecular hydrogen into protons and electrons. These enzymes allow their host organism to grow under chemolithoautotrophic conditions. The model organism Ralstonia eutropha has three well-characterized [NiFe]-hydrogenases, which exhibit an extraordinary high oxygen tolerance. Its active center is a complex prosthetic group which consists of a nickel and iron atom. The latter coordinates three diatomic ligands, two cyanides and one CO. The biosynthesis of the whole Ni(SR)2(μ-SR)2Fe(CN)2(CO)-group is a complex process. This so-called maturation process needs the activity of at least six accessory proteins, the Hyp-proteins. Understanding the maturation allows a variety of biotechnological applications. The present study examines the maturation of [NiFe]-hydrogenases under different aspects. The major questions concern the origin of the carbonyl ligand as well as the processes that lead to ligandation of the designated catalytic iron. To adress these tasks, molecular biological, biochemical and spectroscopic methods in combination with isotopic labeling were employed. Inter alia, it could be shown that the catalytic iron in the HypCD-complex, the central element of the maturation process, contains all three diatomic ligands. Furthermore, this study describes, for the first time in [NiFe]-hydrogenases, a specific biosynthetic route of the rare and toxic diatomic CO-ligand. Starting from the alpha-carbon of glycine the tetrahydrofolate (THF)-dependent one-carbon metabolism is replenished with one-carbon units. Subsequently the formyl group from N10-formyl-THF is hydrolyzed by the enzymatic activity from HypX and further converted to carbon monoxide as determined by isotopic labeling and infrared spectroscopy.

Kohlenmonoxid

Hydrogenase

Ralstonia eutropha

Sauerstofftoleranz

Maturation

Diatomare Liganden

Aktives Zentrum

Tetrahydrofolat

C1-Metabolismus

Ameisensäure

Carbonylligand

CO-Ligand

HypC

HypD

HypX

maturation

carbon monoxide

Hydrogenase

oxygen tolerance

Ralstonia eutropha

diatomic ligands

active site

tetrahydrofolate

one-carbon metabolism

formic acid

carbonyl ligand

CO-ligand

HypC

HypD

HypX

570 Biowissenschaften, Biologie

32 Biologie

WD 5055

ddc:570

Thermal ALD of Cu via Reduction of CuxO films for the Advanced Metallization in Spintronic and ULSI Interconnect Systems

Mueller, Steve, Waechtler, Thomas, Hofmann, Lutz, Tuchscherer, Andre, Mothes, Robert, Gordan, Ovidiu, Lehmann, Daniel, Haidu, Francisc, Ogiewa, Marcel, Gerlich, Lukas, Ding, Shao-Feng, Schulz, Stefan E., Gessner, Thomas, Lang, Heinrich, Zahn, Dietrich R.T., Qu, Xin-Ping

21 February 2012

In this work, an approach for copper atomic layer deposition (ALD) via reduction of CuxO films was investigated regarding applications in ULSI interconnects, like Cu seed layers directly grown on diffusion barriers (e. g. TaN) or possible liner materials (e. g. Ru or Ni) as well as non-ferromagnetic spacer layers between ferromagnetic films in GMR sensor elements, like Ni or Co. The thermal CuxO ALD process is based on the Cu (I) β-diketonate precursor [(nBu3P)2Cu(acac)] and a mixture of water vapor and oxygen ("wet O2") as co-reactant at temperatures between 100 and 130 °C. Highly efficient conversions of the CuxO to metallic Cu films are realized by a vapor phase treatment with formic acid (HCOOH), especially on Ru substrates. Electrochemical deposition (ECD) experiments on Cu ALD seed / Ru liner stacks in typical interconnect patterns are showing nearly perfectly filling behavior. For improving the HCOOH reduction on arbitrary substrates, a catalytic amount of Ru was successful introduced into the CuxO films during the ALD with a precursor mixture of the Cu (I) β-diketonate and an organometallic Ru precursor. Furthermore, molecular and atomic hydrogen were studied as promising alternative reducing agents.

Atomlagenabscheidung

ALD

Ruthenium

Ameisensäure

Wasserstoff

Reduktion

ULSI

Metallisierung

Galvanik

Spintronik

Atomic Layer Deposition

ALD

Copper Oxide

Ruthenium

Formic Acid

Hydrogen

Reduction

ULSI

Interconnect

Electrochemical deposition

ECD

Spintronics

ddc:600

ddc:620

ddc:621

ddc:667

Atomlagenabscheidung

Kupferoxid

Ruthenium

Metallisieren

Galvanische Beschichtung

Kupfer