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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Photosynthetische Wasseroxidation: Über Liganden und Zwischenprodukte / Photosynthetic Water Oxidation:Ligands and Intermediates

Clausen, Jürgen 20 August 2004 (has links)
Photosynthetic water oxidation to yield the oxygen of the atmosphere is of paramount biological and also technical relevance, in the light of decreasing fossil fuel reserves. The splitting of water into hydrogen (on carriers) and oxygen takes place in a multimeric protein called Photosystem II (PSII). The rigorous understanding of nature´s solution for this thermodynamically and mechanistically highly demanding reaction is one approach towards the construction of an artificial hydrogen technology under exploitation of almost unlimited energy sources, sunlight and an ubiquitous substrate, water. This thesis aims at two aspects: (i) Electron and proton transferring amino acids and (ii) so far undetected chemical intermediates between water and O2(i) D1-Glu189 has been claimed to be involved (a) in the proton conducting network around the Mn4Ca-cluster and (b) as a direct ligand to Mn. We exchanged the negative Glu against the positive Arg or Lys or the neutral Glu without any effect on the relaxation times (ns-ms) of the various electron transfers in PSII. Our data exclude these postulated roles of D1-Glu189 and qualify a recently published structural model.(ii) Dioxygen is produced in what seems to be a single reaction step, although it involves the transfer of four electrons from bound water to the fourfold oxidised catalytic centre. No chemical intermediate (e.g. peroxide) has been detected by high resolving optical and magnetical spectroscopy. To overcome the detection problem of short lived intermediates we pushed the process backward by elevated oxygen pressure and found the first evidence for such an intermediate. The astonishing half suppression of oxygen evolution at only 2.3 bar O2 emphasised the small driving force of this important reaction. PSII operates at the energetic limits; this is why the atmospheric oxygen level cannot be pushed much above the present level.
2

Kinetische Untersuchungen zur Reduktion von Nitroaromaten mit Goldnanopartikeln

Fenger, Robert 22 July 2013 (has links)
Goldnanopartikel werden in der kolloidalen Katalyse als Modellsystem genutzt, um den Einfluss des Partikelgröße, der Partikelform und der Zusammensetzung in bimetallischen Systemen sowie der Ligandensphäre auf die katalytische Reduktion von 4-Nitrophenol zu 4-Aminophenol zu untersuchen. Goldnanopartikel eignen sich vor allem deshalb als Modellsystem, da sie in kurzer Zeit, in hohen Ausbeuten und mit definierten Eigenschaften hergestellt werden können. Es konnte erstmals nachgewiesen werden, dass Goldnanopartikel mit einem Durchmesser von 13 nm die höchste katalytische Umsetzungsrate bei der Reduktion von 4-Nitrophenolzu 4-Aminophenol besitzen. Im Zuge dieser Arbeit wird dieses Aktivitätsmaximum der Nanopartikel näher untersucht. Dazu werden drei Aspekte vorgestellt: die Abhängigkeit von der Goldnanopartikelform, die Abhängigkeit der Substratgröße und der Einfluss der Ligandensphäre auf die Katalyse. Überraschenderweise ist CTAB als oberflächenaktiver Ligand ein Co-Katalysator bei der Reduktion, während die Anwesenheit von Natriumcitrat die Reaktion verlangsamt. Es wurden Aspekte wie die Konzentration und die Größe der Goldnanopartikel in dem komplexen Wechselspiel der Aktivitäten des Katalysators und Co-Katalysators untersucht. Dies führte zu der beispielgebenden Erkenntnis, dass oberflächenaktive Liganden mit positiver Ladung und Stickstofffunktionen die Katalyse positiv beeinflussen. In einer weiteren Studie wurde der Reaktionsmechanismus der 6-Elektronenreduktion von 4-Nitrophenol zu 4-Aminophenol erforscht. Es konnte zum ersten Mal gezeigt werden, dass die Reduktion in zwei Teilschritten abläuft. N-Arylhydroxylamin ist als wichtiges Intermediat in der Lösung der Reduktion erstmals nachgewiesen worden. Drei kinetische Regime werden für die Reduktion von 4-Nitrophenol gefunden und geben einen Einblick in die Oberflächenreaktion von Nitroaromaten an Goldnanopartikeln. / Gold nanoparticles as model systems in colloidal catalysis are used to gain insights into the decisive parameters of the catalytic model reduction. Size, shape, composition of bimetallic systems, and ligand sphere are factors influencing the reduction of 4-nitrophenol to 4-aminophenol by sodium borohydride in the presence of gold nanoparticles. The increasing interest in gold nanoparticle catalysis is mainly due to their stability, their fast and high yield synthesis as well as their extraordinary diversity of the modes of preparation. This thesis is assigned to unravel the important parameters of gold nanoparticle catalysis. In the first part of the thesis, CTAB-stabilized gold nanoparticles were synthesized by applying the seeding-growth approach in order to gain information about the size dependence of the catalytic reduction of 4-nitrophenol to 4-aminophenol with sodium borohydride. Unexpectedly, CTAB-stabilized gold nanoparticles with a diameter of 13nm were most efficient in this complex system. In this context, molecular aspects such as shape, size of the substrate and ligand sphere were discussed as possible reasons for the enhanced activity for medium sized gold nanoparticles. Here, it was shown for the first time that the ligand sphere plays a crucial role in colloidal catalysis. Micellar catalysis with colloidal gold nanoparticles was performed by means of ligand exchange procedures. In addition, this thesis shows for the first time that intermediates can be unambiguously identified in the reaction solution with colloidal gold nanoparticles as catalysts. 4-N-hydroxylaminophenol was found to be the key intermediate in this system. In this context, three kinetic regimes which were crucial for the aromatic nitro reduction are found to cover the reaction kinetics. Thus, this thesis provides new insight into the catalytic process itself and leads to a better understanding of the catalytic activity of gold nanoparticles.

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