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Nonlinear lattice dynamics in high-Tc superconductorsPiazza, Francesco January 2002 (has links)
No description available.
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Iron and aluminium speciation in Swedish freshwaters : Implications for geochemical modellingSjöstedt, Carin January 2012 (has links)
Speciation governs transport and toxicity of trace metals and is important to monitor in natural waters. Geochemical models that predict speciation are valuable tools for monitoring. They can be used for risk assessments and future scenarios such as termination of liming. However, there are often large uncertainties concerning the speciation of iron and aluminium in the models, due to the complicated chemistry of these metals. Both are important in governing the speciation of other metals, due to (i) their capacity to form minerals onto which metals can adsorb and (ii) their ability to compete for binding sites to natural organic matter (NOM). Aluminium is also potentially toxic and is therefore closely monitored in acidified freshwaters. In this study different phases of iron in Swedish lakes were characterised. This required a good method for preconcentrating the iron colloids. A new method was developed in this thesis that uses an anion-exchange column to isolate the iron colloids prior to characterisation with extended X-ray absorption fine structure (EXAFS) spectroscopy. Iron was present as ferrihydrite in particles but was also strongly monomerically complexed to NOM in two Swedish lakes. Based on the results an internally consistent process-based geochemical equilibrium model was presented for Swedish freshwaters. The model was validated for pH (n = 9 400) and inorganic monomeric aluminium (Ali) (n = 3 400). The model could simulate pH and Ali simultaneously, and be used for scenario modelling. In this thesis, modelling scenarios for decreases and complete termination of liming are presented for the 3 000 limed Swedish lakes. The results suggest that liming can be terminated in 30 % of the Swedish lakes and decreased in many other lakes. / <p>QC 20120919</p>
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Approche macromoléculaire pour la décorporation d’actinides / Toward a macromolecular approach for the actinides decorporationLahrouch, Florian 14 December 2017 (has links)
Depuis le développement de l'industrie nucléaire, les risques de contamination humaine avec des actinides subsistent et doivent être pris en considération. Le développement des arsenaux nucléaires, les accidents industriels liés à la filière nucléaire civile (Tchernobyl, Fukushima) ou l’utilisation d’armement à l’uranium appauvri dans les conflits armés (Guerre du Golfe, Kosovo) font des contre-mesures visant à décorporer les actinides chez l'homme un enjeu stratégique majeur. Les actinides sont des éléments radiotoxiques et chimiotoxiques (dont la dangerosité dépend de l'isotopie) qui, en cas d’absorption, peuvent provoquer des dommages (cancers, nécroses, etc.) aux tissus et aux organes qu’ils ciblent (foie, reins, squelette). Actuellement l’efficacité de décorporation du chélatant moléculaire de référence, le DTPA (acide diéthylènetriamine pentaacétique), est limitée par sa faible distribution aux organes touchés par la rétention des actinides. Ce projet de thèse constitue une première étape dans l’exploration d’une stratégie de fonctionnalisation macromoléculaire pour vectoriser les agents chélatants vers ces organes cibles de la rétention des actinides dans le but d’augmenter leur excrétion. Pour initier cette problématique, nous avons choisi de nous intéresser aux capacités de complexation de l’uranyle (U(VI)), du plutonium et du thorium (Pu(IV) et Th(IV)) par deux polyéthylèneimines (PEI) fonctionnalisés avec des groupements carboxylate et phosphonate. L’élaboration des courbes de charge associées à la formation des complexes polymériques d’actinides combinées à des études de spectroscopie EXAFS et IR en milieu pseudo-biologique ont permis de définir les capacités de charge maximale de chaque polymère et de caractériser les sites de complexation. Ces données permettent de mieux comprendre les mécanismes d'affinité des polyéthylèneimines fonctionnalisés pour les actinides considérés et donc de progresser dans le design de décorporants. / Since the development of the nuclear industry, the risks of human contamination with actinides are not to be neglected and should be taken in account. Development of the nuclear weapon programs, nuclear plant accidents from civil use (Chernobyl, Fukushima) or use of depleted uranium ammunitions in war zones (Gulf War, Kosovo) have made countermeasures to decorporate actinides in humans an important strategic issue. Actinides are radiotoxic and chemotoxic elements (the relative dangerousness of which depends on their isotopy) which, if absorbed, can cause damages to the tissues and organs they target (bone, liver cancers or necrosis, etc.). To date the efficiency of the molecular decorporation agent of reference, DTPA (diethyleneiminetriamine pentaacetic acid), is limited by its weak distribution rate to the target organs (bone, liver, kidneys). This project explores the possibility to enhance the actinide body excretion using a targeting strategy of the decorporation agent towards the target organs. To initiate this question, we have chosen to focus on the complexing capacities of uranyl (U (VI)), plutonium and thorium (Pu (IV) and Th (IV)) by two polyethyleneimines (PEI) functionalized with carboxylate and phosphonate groups. The measurement of the uptake curves associated with the formation of the actinide polymer complexes combined with EXAFS and IR spectroscopic studies in a pseudo-biological medium made it possible to define the maximum loading capacities of each polymer and to characterize the complexation sites. These data allow to better understand the mechanisms of affinity of the functionalized polyethyleneimines for the above actinides and thus to progress in the design of new decorporation agents.
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Homogeneity and elemental distribution in self-assembled bimetallic Pd–Pt aerogels prepared by a spontaneous one-step gelation processSchmidt, Thomas Justus, Oezaslan, Methap, Liu, W., Nachtegaal, Maarten, Frenkel, Anatoly I., Rutkowski, B., Werheid, Matthias, Herrmann, Anne-Kristin, Laugier-Bonnaud, C., Yilmaz, H.-C., Gaponik, Nikolai, Czyrska-Filemonowicz, A., Eychmüller, Alexander 06 April 2017 (has links) (PDF)
Multi-metallic aerogels have recently emerged as a novel and promising class of unsupported electrocatalyst materials due to their high catalytic activity and improved durability for various electrochemical reactions. Aerogels can be prepared by a spontaneous one-step gelation process, where the chemical co-reduction of metal precursors and the prompt formation of nanochain-containing hydrogels, as a preliminary stage for the preparation of aerogels, take place. However, detailed knowledge about the homogeneity and chemical distribution of these three-dimensional Pd–Pt aerogels at the nano-scale as well as at the macro-scale is still unclear. Therefore, we used a combination of spectroscopic and microscopic techniques to obtain a better insight into the structure and elemental distribution of the various Pd-rich Pd–Pt aerogels prepared by the spontaneous one-step gelation process. Synchrotron-based extended X-ray absorption fine structure (EXAFS) spectroscopy and high-angle annular dark-field (HAADF) scanning transmission electron microscopy (STEM) in combination with energy-dispersive X-ray spectroscopy (EDX) were employed in this work to uncover the structural architecture and chemical composition of the various Pd-rich Pd–Pt aerogels over a broad length range. The Pd80Pt20, Pd60Pt40 and Pd50Pt50 aerogels showed heterogeneity in the chemical distribution of the Pt and Pd atoms inside the macroscopic nanochain-network. The features of mono-metallic clusters were not detected by EXAFS or STEM-EDX, indicating alloyed nanoparticles. However, the local chemical composition of the Pd–Pt alloys strongly varied along the nanochains and thus within a single aerogel. To determine the electrochemically active surface area (ECSA) of the Pd–Pt aerogels for application in electrocatalysis, we used the electrochemical CO stripping method. Due to their high porosity and extended network structure, the resulting values of the ECSA for the Pd–Pt aerogels were higher than that for a commercially available unsupported Pt black catalyst. We show that the Pd–Pt aerogels possess a high utilization of catalytically active centers for electrocatalytic applications based on the nanostructured bimetallic framework. Knowledge about the homogeneity and chemical distribution of the bimetallic aerogels can help to further optimize their preparation by the spontaneous one-step gelation process and to tune their electrocatalytic reactivity.
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Coordination Chemistry of Monocarboxylate and Aminocarboxylate Complexes at the Water/Goethite InterfaceNorén, Katarina January 2007 (has links)
<p>This thesis is a summary of five papers with focus on adsorption processes of various monocarboxylates and aminocarboxylates at the water/goethite interface. Interaction of organic acids at the water/mineral interfaces are of importance in biogeochemical processes, since such processes have potential to alter mobility and bioavailability of the acids and metal ions.</p><p>In order to determine the coordination chemistry of acetate, benzoate, cyclohexanecarboxylate, sarcosine, MIDA (methyliminediacetic acid), EDDA (ethylenediamine-N,N’-diacetic acid) and EDTA (ethylenediamine-N,N’-tetraacetic acid) upon adsorption to the goethite (alpha-FeOOH) surface, a combination of quantitative measurements with attenuated total reflectance Fourier transform infrared spectroscopy (ATR-FTIR) was utilized.</p><p>Over the pH range studied here (pH 3- 9) all ligands, except for sarcosine, have been found to form surface complexes with goethite. In general, theses were characterized as outer sphere surface complexes i.e. with no direct interaction with surface Fe(III) metal ions. Furthermore, two types of different outer-sphere complexes were identified, the solvent-surface hydration-separated ion pair, and hydration-shared ion pair. For the monocarboxylate surface complexes distinction between these two could be made. At high pH values the solvent-surface hydration-separated ion pair was the predominating complex, while at low pH the surface complex is stabilized through the formation of strong hydrogen bonds with the goethite surface. However, it was not possible to clearly separate between the two outer-sphere complexes for coordination of the aminocarboxylates with the surface of goethite. Additionally, EDDA also formed an inner-sphere surface complex at high pH values. The EDDA molecule was suggested to coordinate to the surface by forming a five membered ring with an iron at the goethite surface, through the amine and carboxylate groups.</p><p>Contrary to the other ligands studied, EDTA significantly induced dissolution of goethite. Some of the dissolved iron, in the form of the highly stable FeEDTA- solution complex, was indicated to re-adsorb to the mineral surface as a ternary complex. Similar ternary surface complexes were also found in the Ga(III)EDTA/goethite system, and quantitative and spectroscopic studies on adsorption of Ga(III) in presence and absence of EDTA showed that EDTA considerably effects speciation of gallium at goethite surface.</p><p>The collective results in this thesis show that the affinity of these ligands for the surface of goethite is primarily governed by their chemical composition and structure, and especially important are the types, numbers and relative position of functional groups within the molecular structure.</p>
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Coordination Chemistry of Monocarboxylate and Aminocarboxylate Complexes at the Water/Goethite InterfaceNorén, Katarina January 2007 (has links)
This thesis is a summary of five papers with focus on adsorption processes of various monocarboxylates and aminocarboxylates at the water/goethite interface. Interaction of organic acids at the water/mineral interfaces are of importance in biogeochemical processes, since such processes have potential to alter mobility and bioavailability of the acids and metal ions. In order to determine the coordination chemistry of acetate, benzoate, cyclohexanecarboxylate, sarcosine, MIDA (methyliminediacetic acid), EDDA (ethylenediamine-N,N’-diacetic acid) and EDTA (ethylenediamine-N,N’-tetraacetic acid) upon adsorption to the goethite (alpha-FeOOH) surface, a combination of quantitative measurements with attenuated total reflectance Fourier transform infrared spectroscopy (ATR-FTIR) was utilized. Over the pH range studied here (pH 3- 9) all ligands, except for sarcosine, have been found to form surface complexes with goethite. In general, theses were characterized as outer sphere surface complexes i.e. with no direct interaction with surface Fe(III) metal ions. Furthermore, two types of different outer-sphere complexes were identified, the solvent-surface hydration-separated ion pair, and hydration-shared ion pair. For the monocarboxylate surface complexes distinction between these two could be made. At high pH values the solvent-surface hydration-separated ion pair was the predominating complex, while at low pH the surface complex is stabilized through the formation of strong hydrogen bonds with the goethite surface. However, it was not possible to clearly separate between the two outer-sphere complexes for coordination of the aminocarboxylates with the surface of goethite. Additionally, EDDA also formed an inner-sphere surface complex at high pH values. The EDDA molecule was suggested to coordinate to the surface by forming a five membered ring with an iron at the goethite surface, through the amine and carboxylate groups. Contrary to the other ligands studied, EDTA significantly induced dissolution of goethite. Some of the dissolved iron, in the form of the highly stable FeEDTA- solution complex, was indicated to re-adsorb to the mineral surface as a ternary complex. Similar ternary surface complexes were also found in the Ga(III)EDTA/goethite system, and quantitative and spectroscopic studies on adsorption of Ga(III) in presence and absence of EDTA showed that EDTA considerably effects speciation of gallium at goethite surface. The collective results in this thesis show that the affinity of these ligands for the surface of goethite is primarily governed by their chemical composition and structure, and especially important are the types, numbers and relative position of functional groups within the molecular structure.
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Homogeneity and elemental distribution in self-assembled bimetallic Pd–Pt aerogels prepared by a spontaneous one-step gelation processSchmidt, Thomas Justus, Oezaslan, Methap, Liu, W., Nachtegaal, Maarten, Frenkel, Anatoly I., Rutkowski, B., Werheid, Matthias, Herrmann, Anne-Kristin, Laugier-Bonnaud, C., Yilmaz, H.-C., Gaponik, Nikolai, Czyrska-Filemonowicz, A., Eychmüller, Alexander 06 April 2017 (has links)
Multi-metallic aerogels have recently emerged as a novel and promising class of unsupported electrocatalyst materials due to their high catalytic activity and improved durability for various electrochemical reactions. Aerogels can be prepared by a spontaneous one-step gelation process, where the chemical co-reduction of metal precursors and the prompt formation of nanochain-containing hydrogels, as a preliminary stage for the preparation of aerogels, take place. However, detailed knowledge about the homogeneity and chemical distribution of these three-dimensional Pd–Pt aerogels at the nano-scale as well as at the macro-scale is still unclear. Therefore, we used a combination of spectroscopic and microscopic techniques to obtain a better insight into the structure and elemental distribution of the various Pd-rich Pd–Pt aerogels prepared by the spontaneous one-step gelation process. Synchrotron-based extended X-ray absorption fine structure (EXAFS) spectroscopy and high-angle annular dark-field (HAADF) scanning transmission electron microscopy (STEM) in combination with energy-dispersive X-ray spectroscopy (EDX) were employed in this work to uncover the structural architecture and chemical composition of the various Pd-rich Pd–Pt aerogels over a broad length range. The Pd80Pt20, Pd60Pt40 and Pd50Pt50 aerogels showed heterogeneity in the chemical distribution of the Pt and Pd atoms inside the macroscopic nanochain-network. The features of mono-metallic clusters were not detected by EXAFS or STEM-EDX, indicating alloyed nanoparticles. However, the local chemical composition of the Pd–Pt alloys strongly varied along the nanochains and thus within a single aerogel. To determine the electrochemically active surface area (ECSA) of the Pd–Pt aerogels for application in electrocatalysis, we used the electrochemical CO stripping method. Due to their high porosity and extended network structure, the resulting values of the ECSA for the Pd–Pt aerogels were higher than that for a commercially available unsupported Pt black catalyst. We show that the Pd–Pt aerogels possess a high utilization of catalytically active centers for electrocatalytic applications based on the nanostructured bimetallic framework. Knowledge about the homogeneity and chemical distribution of the bimetallic aerogels can help to further optimize their preparation by the spontaneous one-step gelation process and to tune their electrocatalytic reactivity.
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