@phdthesis{Walther2018,
  author    = {Walther, Sebastian},
  title     = {Funktionalisierung von {\"O}ls{\"a}uremethylester und Alkydharzen f{\"u}r die photoinduzierte radikalische Polymerisation im UV Bereich},
  url       = {http://nbn-resolving.de/urn:nbn:de:kobv:517-opus4-421467},
  school      = {Universit{\"a}t Potsdam},
  pages     = {136},
  year      = {2018},
  abstract  = {Die vorliegende Arbeit behandelt die Synthese und Charakterisierung von funktionalisierten Alkydharzen und die photoinduzierte Polymerisation dieser unter Einsatz einer Quecksilberdampflampe oder einer UV LED mit unterschiedlicher Lichtintensit{\"a}t. Der Fokus dieser Arbeit bestand in der gezielten Substitution der internalen Doppelbindungen der Fetts{\"a}ureester durch reaktivere Gruppen, wie Acrylate oder Methacrylate, welche f{\"u}r Alkydharze in dieser Form so in der Literatur nicht beschrieben sind. Untersuchungen des Polymerisationsverhaltens dieser funktionalisierten Harze wurden mit der Photo DSC durchgef{\"u}hrt, wobei Bis - (4 - methoxybenzoyl) diethylgermanium als Photoinitiator diente. Die Ergebnisse haben gezeigt, dass die Harze radikalisch polymerisiert werden k{\"o}nnen und eine geringere Abh{\"a}ngigkeit von der Umgebungsatmosph{\"a}re (Luftsauerstoff bzw. Stickstoff) vorliegt. Dies ist so in der Literatur f{\"u}r funktionalisierte Alkydharze nicht bekannt. Abmischungen von unterschiedlichen Monomeren und funktionalisierten Harzen bewirkten eine Steigerung der Viskosit{\"a}t sowie eine Verringerung der Sauerstoffinhibierung im Zuge der photoinduzierten Polymerisation unter Luftsauerstoff f{\"u}r die Quecksilberdampflampe und der UV LED. Zur Untersuchung der sauerstoffinhibierenden Wirkung der Harze sind Synthesen unterschiedlicher, funktionalisierter {\"O}ls{\"a}uremethylester als Modellsubstanzen durchgef{\"u}hrt worden. Ein verbessertes Polymerisationsverhalten und eine geringe Abh{\"a}ngigkeit von der Umgebungsatmosph{\"a}re konnte f{\"u}r die Modelle nachgewiesen werden. Zur Aufkl{\"a}rung des verbesserten Polymerisationsverhaltens sind gezielt Substituenten (Imidazol, Brom, Alkohol, Acetat) in den funktionalisierten {\"O}ls{\"a}uremethylester eingebaut worden, um den Einfluss dieser aufzuzeigen. Im Rahmen dieser Synthesen sind neuartige Strukturen synthetisiert worden, welche so in der Literatur nicht beschrieben sind. Die Gegen{\"u}berstellung der Polymerisationszeit, der Umsatz der (Meth-)Acrylatgruppen sowie die Zeit zum Erreichen der maximalen Polymerisationsgeschwindigkeit unter Verwendung von unterschiedlichen UV Lichtquellen hat einen Einfluss der Substituenten auf das Polymerisationsverhalten gezeigt.},
  language  = {de}
}
@phdthesis{Karras2018,
  author    = {Karras, Manfred},
  title     = {Synthesis of enantiomerically pure helical aromatics such as NHC ligands and their use in asymmetric catalysis},
  url       = {http://nbn-resolving.de/urn:nbn:de:kobv:517-opus4-421497},
  school      = {Universit{\"a}t Potsdam},
  pages     = {121},
  year      = {2018},
  abstract  = {Diese Arbeit besch{\"a}ftigt sich mit der enantiomerenreinen Synthese helikaler, aromatischer Verbindungen. Verschiedene Verbindungen dieses Typs wurden erfolgreich hergestellt und charakterisiert. Desweiteren wurden einige der neuen Verbindungen in {\"U}bergangsmetallkomplexe eingebaut und diese dann als Katalysatoren f{\"u}r Metathese und Kreuzkupplungen getestet. Einer der getesteten Katalysatoren zeigte vielversprechende Ergebnisse in der asymmetrischen Olefinmetathese. Die Struktur des neuen Katalysators wurde untersucht. Anhand der Struktur des neuen Katalysators wurden R{\"u}ckschl{\"u}sse auf einen m{\"o}glichen Mechanismus gezogen.},
  language  = {en}
}
@phdthesis{VillatoroLeal2018,
  author    = {Villatoro Leal, Jos{\´e} Andr{\´e}s},
  title     = {A combined approach for the analysis of biomolecules using IR-MALDI ion mobility spectrometry and molecular dynamics simulations of peptide ions in the gas phase},
  url       = {http://nbn-resolving.de/urn:nbn:de:kobv:517-opus4-419723},
  school      = {Universit{\"a}t Potsdam},
  pages     = {133},
  year      = {2018},
  abstract  = {The aim of this doctoral thesis was to establish a technique for the analysis of biomolecules with infrared matrix-assisted laser dispersion (IR-MALDI) ion mobility (IM) spectrometry. The main components of the work were the characterization of the IR-MALDI process, the development and characterization of different ion mobility spectrometers, the use of IR-MALDI-IM spectrometry as a robust, standalone spectrometer and the development of a collision cross-section estimation approach for peptides based on molecular dynamics and thermodynamic reweighting. First, the IR-MALDI source was studied with atmospheric pressure ion mobility spectrometry and shadowgraphy. It consisted of a metal capillary, at the tip of which a self-renewing droplet of analyte solution was met by an IR laser beam. A relationship between peak shape, ion desolvation, diffusion and extraction pulse delay time (pulse delay) was established. First order desolvation kinetics were observed and related to peak broadening by diffusion, both influenced by the pulse delay. The transport mechanisms in IR-MALDI were then studied by relating different laser impact positions on the droplet surface to the corresponding ion mobility spectra. Two different transport mechanisms were determined: phase explosion due to the laser pulse and electrical transport due to delayed ion extraction. The velocity of the ions stemming from the phase explosion was then measured by ion mobility and shadowgraphy at different time scales and distances from the source capillary, showing an initially very high but rapidly decaying velocity. Finally, the anatomy of the dispersion plume was observed in detail with shadowgraphy and general conclusions over the process were drawn. Understanding the IR-MALDI process enabled the optimization of the different IM spectrometers at atmospheric and reduced pressure (AP and RP, respectively). At reduced pressure, both an AP and an RP IR-MALDI source were used. The influence of the pulsed ion extraction parameters (pulse delay, width and amplitude) on peak shape, resolution and area was systematically studied in both AP and RP IM spectrometers and discussed in the context of the IR-MALDI process. Under RP conditions, the influence of the closing field and of the pressure was also examined for both AP and RP sources. For the AP ionization RP IM spectrometer, the influence of the inlet field (IF) in the source region was also examined. All of these studies led to the determination of the optimal analytical parameters as well as to a better understanding of the initial ion cloud anatomy. The analytical performance of the spectrometer was then studied. Limits of detection (LOD) and linear ranges were determined under static and pulsed ion injection conditions and interpreted in the context of the IR-MALDI mechanism. Applications in the separation of simple mixtures were also illustrated, demonstrating good isomer separation capabilities and the advantages of singly charged peaks. The possibility to couple high performance liquid chromatography (HPLC) to IR-MALDI-IM spectrometry was also demonstrated. Finally, the reduced pressure spectrometer was used to study the effect of high reduced field strength on the mobility of polyatomic ions in polyatomic gases. The last focus point was on the study of peptide ions. A dataset obtained with electrospray IM spectrometry was characterized and used for the calibration of a collision cross-section (CCS) determination method based on molecular dynamics (MD) simulations at high temperature. Instead of producing candidate structures which are evaluated one by one, this semi-automated method uses the simulation as a whole to determine a single average collision cross-section value by reweighting the CCS of a few representative structures. The method was compared to the intrinsic size parameter (ISP) method and to experimental results. Additional MD data obtained from the simulations was also used to further analyze the peptides and understand the experimental results, an advantage with regard to the ISP method. Finally, the CCS of peptide ions analyzed by IR-MALDI were also evaluated with both ISP and MD methods and the results compared to experiment, resulting in a first validation of the MD method. Thus, this thesis brings together the soft ionization technique that is IR-MALDI, which produces mostly singly charged peaks, with ion mobility spectrometry, which can distinguish between isomers, and a collision cross-section determination method which also provides structural information on the analyte at hand.},
  language  = {en}
}
@phdthesis{Dai2018,
  author    = {Dai, Xiaolin},
  title     = {Synthesis of artificial building blocks for sortase-mediated ligation and their enzymatic linkage},
  url       = {http://nbn-resolving.de/urn:nbn:de:kobv:517-opus4-420060},
  school      = {Universit{\"a}t Potsdam},
  pages     = {XIV, 125},
  year      = {2018},
  abstract  = {Das Enzym Sortase A katalysiert die Bildung einer Peptidbindung zwischen der Erkennungssequenz LPXTG und einem Oligoglycin. W{\"a}hrend vielf{\"a}ltige Ligationen zwischen Proteinen und verschiedenen Biomolek{\"u}len, Proteinen und kleinen synthetischen Molek{\"u}len, sowie Proteinen und Oberfl{\"a}chen durchgef{\"u}hrt wurden, besteht das Ziel dieser Arbeit darin, die Sortase-katalysierte Verlinkung von synthetischen Bausteinen zu untersuchen. Dies k{\"o}nnte den Weg bereiten f{\"u}r die Anwendung von Sortase A f{\"u}r chemische Aufgabenstellungen und eventuell sogar in den Materialwissenschaften. F{\"u}r diese grunds{\"a}tzliche Untersuchung wurden die verwendeten Bausteine zun{\"a}chst so einfach wie m{\"o}glich gehalten und leicht zug{\"a}ngliche SiO2 Nanopartikel und kommerziell erh{\"a}ltliche Polymerbl{\"o}cke ausgew{\"a}hlt. Die Bausteine wurden als erstes mit den Peptidsequenzen f{\"u}r Sortase-vermittelte Ligationen funktionalisiert. SiO2 Nanopartikel wurden mit Durchmessern von 60 und 200 nm hergestellt und mit C=C Doppelbindungen oberfl{\"a}chenmodifiziert. Dann wurden Peptide mit einem terminalen Cystein kovalent durch eine Thiol-en Reaktion angebunden. An die 60 nm NP wurden Peptide mit einem Pentaglycin und an die 200 nm Partikel Peptide mit LPETG Sequenz gebunden. Auf die gleiche Art und Weise wurden Peptide mit terminalem Cystein an die Polymere Polyethylenglykol (PEG) und Poly(N Isopropylacrylamid) (PNIPAM), die beide {\"u}ber C=C Endgruppen verf{\"u}gen, gebunden und G5-PEG und PNIPAM-LPETG Konjugate erhalten. Mit den vier Bausteinen wurden nun durch Sortase-vermittelte Ligation NP-Polymer Hybride, NP-NP und Polymer-Polymer Strukturen hergestellt und die Produkte u. a. durch Transmissionselektronen-mikroskopie, MALDI-ToF Massenspektrometrie sowie Dynamische Lichtstreuung charakterisiert. Die Verlinkung dieser synthetischen Bausteine konnte eindeutig gezeigt werden. Das Verwenden von kommerziell erh{\"a}ltlichen Polymeren hat jedoch zu einem Gemisch der Polymer-Peptid Konjugate mit unmodifiziertem Polymer gef{\"u}hrt, welches nicht gereinigt werden konnte. Deswegen wurden anschließend Synthesestrategien f{\"u}r reine Peptid-Polymer und Polymer-Peptid Konjugate als Bausteine f{\"u}r Sortase-vermittelte Ligationen entwickelt. Diese basieren auf der RAFT Polymerisation mit CTAs, die entweder an N- oder C-Terminus eines Peptids gebunden sind. GG-PNIPAM wurde durch das Anbinden eines geeigneten RAFT CTAs an Fmoc-GG in einer Veresterungsreaktion, Polymerisation von NIPAM und Abspalten der Fmoc Schutzgruppe synthetisiert. Weiterhin wurden mehrere Peptide durch Festphasen-Peptidsynthese erhalten. Die Anbindung eines RAFT CTAs (oder eines Polymerisationsinitiators) an den N-Terminus eines Peptids kann automatisiert als letzter Schritt in einem Peptid-Synthetisierer erfolgen. Die Synthese eines solchen Konjugats konnte in dem Zeithorizont dieser Arbeit noch nicht erreicht werden. Jedoch existieren mehrere vielversprechende Strategien, um diesen Ansatz mit verschiedenen Kopplungsreagenzien zur Anbindung des CTAs fortzusetzen. Solche Polymer Bausteine k{\"o}nnen in Zukunft f{\"u}r die Synthese von Protein-Polymer Konjugaten durch Sortase-Katalyse verwendet werden. Außerdem kann der Ansatz auch f{\"u}r die Synthese von Block-Copolymeren aus Polymerbl{\"o}cken mit Peptidmotiven an beiden Enden ausgebaut werden. Auch wenn bei der grunds{\"a}tzlichen Untersuchung im Rahmen dieser Arbeit Hybridstrukturen hergestellt wurden, die auch durch traditionelle chemische Synthesen erhalten werden k{\"o}nnten, wird ein Bausatz solcher Bausteine in Zukunft die Synthese neuer Materialien erm{\"o}glichen und kann auch den Weg f{\"u}r die Anwendung von Enzymen in den Materialwissenschaften ebnen. In Erg{\"a}nzung zu Nanopartikeln und Block-Copolymeren k{\"o}nnen dann auch Hybridmaterialien unter Einbezug von Protein-basierten Bausteinen hergestellt werden. Daher k{\"o}nnten Sortase Enzyme zu einem Werkzeug werden, welches etablierte chemische Verlinkungstechniken erg{\"a}nzt und mit den hoch spezifischen Peptidmotiven {\"u}ber funktionale Einheiten verf{\"u}gt, die orthogonal zu allen chemischen Gruppen sind.},
  language  = {en}
}
@phdthesis{Roder2018,
  author    = {Roder, Phillip},
  title     = {Kombination von Fluoreszenzmikroskopie und Rasterkraftmikroskopie zur Aufkl{\"a}rung physiologischer Prozesse in lebenden Zellen},
  url       = {http://nbn-resolving.de/urn:nbn:de:kobv:517-opus4-419806},
  school      = {Universit{\"a}t Potsdam},
  pages     = {xvi, 113},
  year      = {2018},
  abstract  = {Innerhalb dieser Doktorarbeit wurde eine neuartige Mikromanipulationstechnik f{\"u}r die lokale Fl{\"u}ssigkeitsabgabe am komplexen Dr{\"u}sengewebe der Schabe P. americana charakterisiert und f{\"u}r die damit verbundene gezielte Manipulation von einzelnen Zellen in einem Zellkomplex (Gewebe) angewandt. Bei dieser Mikromanipulationstechnik handelt es sich um die seit 2009 bekannte nanofluidische Rasterkraftmikroskopie (FluidFM = fluidic force microscopy). Dabei werden sehr kleine mikrokan{\"a}lige Rasterkraftspitzen bzw. Mikro-/Nanopipetten mit einer {\"O}ffnung zwischen 300 nm und 2 µm verwendet, mit denen es m{\"o}glich ist, sehr kleine Volumina im Pikoliter- bis Femtoliter-Bereich (10-12 L - 10-15 L) gezielt und ortsgenau abzugeben. Das Ziel dieser Arbeit war die Analyse zellul{\"a}rer Prozesse, wie z. B. Zell-Zell-Kommunikation oder Signalweiterleitung, zwischen benachbarten Zellen unter Zuhilfenahme der Fluoreszenzmikroskopie. Mit dieser Methode k{\"o}nnen die Zellen und ihre Bestandteile mittels vorheriger Farbstoffbeladung unter einem Mikroskop mit hohem Kontrast optisch dargestellt werden. Mit Hilfe der Fluoreszenzmikroskopie sollten schlussendlich die zellul{\"a}ren Reaktionen innerhalb des Gewebes nach der lokalen Manipulation visualisiert werden. Zun{\"a}chst wurde die Anwendung des Systems an Luft und w{\"a}ssriger Umgebung beschrieben. In diesem Zusammenhang wurde eine Reinigungs- und Beladungsmethode entwickelt, mit der es m{\"o}glich war, die kostspieligen Mikro-/Nanopipetten zu reinigen und anschließend mehrmals wiederzuverwenden. Hierzu wurde eine alternative Methode getestet, mit der das Diffusionsverhalten von Farbstoffmolek{\"u}len in unterschiedlichen Medien untersucht werden kann. Des Weiteren wurden die Systemparameter optimiert, welche n{\"o}tig sind, um zwischen der Probenoberfl{\"a}che und der Pipette einen guten Pipetten{\"o}ffnungs-abschluss zu erhalten. Dieser Abschluss ist essentiell, damit die abgegebene Fl{\"u}ssigkeit ausschließlich in der Abgaberegion mit der Probe wechselwirkt und die darauffolgenden Reaktionen nur innerhalb des Gewebes erfolgen, da ansonsten die Zell-Zell-Signalweiterleitung zwischen den Zellen nicht eindeutig nachvollzogen werden kann. Diese interzellul{\"a}re Kommunikation wurde anhand zweier sekund{\"a}rer Botenstoffe (Ca2+ und NO) untersucht. Hierbei war es m{\"o}glich einzelne lokale Reaktionen zu detektieren, welche sich {\"u}ber weitere Zellen ausbreiteten. Schlussendlich wurde die Fertigung einer speziellen Injektionspipette beschrieben, welche an zwei biologischen Systemen getestet wurde.},
  language  = {de}
}
@phdthesis{Abouserie2018,
  author    = {Abouserie, Ahed},
  title     = {Ionic liquid precursors for multicomponent inorganic nanomaterials},
  url       = {http://nbn-resolving.de/urn:nbn:de:kobv:517-opus4-418950},
  school      = {Universit{\"a}t Potsdam},
  pages     = {xx, 193},
  year      = {2018},
  abstract  = {Health effects, attributed to the environmental pollution resulted from using solvents such as benzene, are relatively unexplored among petroleum workers, personal use, and laboratory researchers. Solvents can cause various health problems, such as neurotoxicity, immunotoxicity, and carcinogenicity. As such it can be absorbed via epidermal or respiratory into the human body resulting in interacting with molecules that are responsible for biochemical and physiological processes of the brain. Owing to the ever-growing demand for finding a solution, an Ionic liquid can use as an alternative solvent. Ionic liquids are salts in a liquid state at low temperature (below 100 C), or even at room temperature. Ionic liquids impart a unique architectural platform, which has been interesting because of their unusual properties that can be tuned by simple ways such as mixing two ionic liquids. Ionic liquids not only used as reaction solvents but they became a key developing for novel applications based on their thermal stability, electric conductivity with very low vapor pressure in contrast to the conventional solvents. In this study, ionic liquids were used as a solvent and reactant at the same time for the novel nanomaterials synthesis for different applications including solar cells, gas sensors, and water splitting. The field of ionic liquids continues to grow, and become one of the most important branches of science. It appears to be at a point where research and industry can work together in a new way of thinking for green chemistry and sustainable production.},
  language  = {en}
}
@phdthesis{Behrendt2018,
  author    = {Behrendt, Felix Nicolas},
  title     = {New bio-based polymers},
  url       = {http://nbn-resolving.de/urn:nbn:de:kobv:517-opus4-418316},
  school      = {Universit{\"a}t Potsdam},
  pages     = {vii, 153},
  year      = {2018},
  abstract  = {Redox-responsive polymers, such as poly(disulfide)s, are a versatile class of polymers with potential applications including gene- and drug-carrier systems. Their degradability under reductive conditions allows for a controlled response to the different redox states that are present throughout the body. Poly(disulfide)s are typically synthesized by step growth polymerizations. Step growth polymerizations, however, may suffer from low conversions and therefore low molar masses, limiting potential applications. The purpose of this thesis was therefore to find and investigate new synthetic routes towards the synthesis of amino acid-based poly(disulfide)s. The different routes in this thesis include entropy-driven ring opening polymerizations of novel macrocyclic monomers, derived from cystine derivatives. These monomers were obtained with overall yields of up to 77\% and were analyzed by mass spectrometry as well as by 1D and 2D NMR spectroscopy. The kinetics of the entropy-driven ring-opening metathesis polymerization (ED-ROMP) were thoroughly investigated in dependence of temperature, monomer concentration, and catalyst concentration. The polymerization was optimized to yield poly(disulfide)s with weight average molar masses of up to 80 kDa and conversions of ~80\%, at the thermodynamic equilibrium. Additionally, an alternative metal free polymerization, namely the entropy-driven ring-opening disulfide metathesis polymerization (ED-RODiMP) was established for the polymerization of the macrocyclic monomers. The effect of different solvents, concentrations and catalyst loadings on the polymerization process and its kinetics were studied. Polymers with very high weight average molar masses of up to 177 kDa were obtained. Moreover, various post-polymerization reactions were successfully performed. This work provides the first example of the homopolymerization of endo-cyclic disulfides by ED-ROMP and the first substantial study into the kinetics of the ED-RODiMP process.},
  language  = {en}
}
@phdthesis{Xiong2018,
  author    = {Xiong, Tao},
  title     = {Vibrationally resolved absorption, emission, resonance Raman and photoelectron spectra of selected organic molecules, associated radicals and cations},
  url       = {http://nbn-resolving.de/urn:nbn:de:kobv:517-opus4-418105},
  school      = {Universit{\"a}t Potsdam},
  pages     = {iv, 100},
  year      = {2018},
  abstract  = {Time-dependent correlation function based methods to study optical spectroscopy involving electronic transitions can be traced back to the work of Heller and coworkers. This intuitive methodology can be expected to be computationally efficient and is applied in the current work to study the vibronic absorption, emission, and resonance Raman spectra of selected organic molecules. Besides, the "non-standard" application of this approach to photoionization processes is also explored. The application section consists of four chapters as described below. In Chapter 4, the molar absorptivities and vibronic absorption/emission spectra of perylene and several of its N-substituted derivatives are investigated. By systematically varying the number and position of N atoms, it is shown that the presence of nitrogen heteroatoms has a negligible effect on the molecular structure and geometric distortions upon electronic transitions, while spectral properties are more sensitive: In particular the number of N atoms is important while their position is less decisive. Thus, N-substitution can be used to fine-tune the optical properties of perylene-based molecules. In Chapter 5, the same methods are applied to study the vibronic absorption/emission and resonance Raman spectra of a newly synthesized donor-acceptor type molecule. The simulated absorption/emission spectra agree fairly well with experimental data, with discrepancies being attributed to solvent effects. Possible modes which may dominate the fine-structure in the vibronic spectra are proposed by analyzing the correlation function with the aid of Raman and resonance Raman spectra. In the next two chapters, besides the above types of spectra, the methods are extended to study photoelectron spectra of several small diamondoid-related systems (molecules, radicals, and cations). Comparison of the photoelectron spectra with available experimental data suggests that the correlation function based approach can describe ionization processes reasonably well. Some of these systems, cationic species in particular, exhibit somewhat peculiar optical behavior, which presents them as possible candidates for functional devices. Correlation function based methods in a more general sense can be very versatile. In fact, besides the above radiative processes, formulas for non-radiative processes such as internal conversion have been derived in literature. Further implementation of the available methods is among our next goals.},
  language  = {en}
}
@phdthesis{Tan2018,
  author    = {Tan, Li},
  title     = {Synthesis, assembly and thermo-responsivity of polymer-functionalized magnetic cobalt nanoparticles},
  url       = {http://nbn-resolving.de/urn:nbn:de:kobv:517-opus4-418153},
  school      = {Universit{\"a}t Potsdam},
  pages     = {X, 111},
  year      = {2018},
  abstract  = {This thesis mainly covers the synthesis, surface modification, magnetic-field-induced assembly and thermo-responsive functionalization of superparamagnetic Co NPs initially stabilized by hydrophobic small molecules oleic acid (OA) and trioctylphosphine oxide (TOPO), as well as the synthesis of both superparamagnetic and ferromagnetic Co NPs by using end-functionalized-polystyrene as stabilizer. Co NPs, due to their excellent magnetic and catalytic properties, have great potential application in various fields, such as ferrofluids, catalysis, and magnetic resonance imaging (MRI). Superparamagnetic Co NPs are especially interesting, since they exhibit zero coercivity. They get magnetized in an external magnetic field and reach their saturation magnetization rapidly, but no magnetic moment remains after removal of the applied magnetic field. Therefore, they do not agglomerate in the body when they are used in biomedical applications. Normally, decomposition of metallic precursors at high temperature is one of the most important methods in preparation of monodisperse magnetic NPs, providing tunability in size and shape. Hydrophobic ligands like OA, TOPO and oleylamine are often used to both control the growth of NPs and protect them from agglomeration. The as-prepared magnetic NPs can be used in biological applications as long as they are transferred into water. Moreover, their supercrystal assemblies have the potential for high density data storage and electronic devices. In addition to small molecules, polymers can also be used as surfactants for the synthesis of ferromagnetic and superparamagnetic NPs by changing the reaction conditions. Therefore, chapter 2 gives an overview on the basic concept of synthesis, surface modification and self-assembly of magnetic nanoparticles. Various examples were used to illustrate the recent work. The hydrophobic Co NPs synthesized with small molecules as surfactants limit their biological applications, which require a hydrophilic or aqueous environment. Surface modification (e.g., ligand exchange) is a general idea for either phase transition or surface-functionalization. Therefore, in chapter 3, a ligand exchange process was conducted to functionalize the surface of Co NPs. PNIPAM is one of the most popular smart polymers and its lower critical solution temperature (LCST) is around 32 °C, with a reversible change in the conformation structure between hydrophobic and hydrophilic. The novel nanocomposites of superparamagnetic Co NPs and thermo-responsive PNIPAM are of great interest. Thus, well-defined superparamagnetic Co NPs were firstly synthesized through the thermolysis of cobalt carbonyl by using OA and TOPO as surfactants. A functional ATRP initiator, containing an amine (as anchoring group) and a 2-bromopropionate group (SI-ATRP initiator), was used to replace the original ligands. This process is rapid and facial for efficient surface functionalization and afterwards the Co NPs can be dispersed into polar solvent DMF without aggregation. FT-IR spectroscopy showed that the TOPO was completely replaced, but a small amount of OA remained on the surface. A TGA measurement allowed the calculation of the grafting density of the initiator as around 3.2 initiator/nm2. Then, the surface-initiated ATRP was conducted for the polymerization of NIPAM on the surface of Co NPs and rendered the nanocomposites water-dispersible. A temperature-dependent dynamic light scattering study showed the aggregation behavior of PNIPAM-coated Co NPs upon heating and this process was proven to be reversible. The combination of superparamagnetic and thermo-responsive properties in these hybrid nanoparticles is promising for future applications e.g. in biomedicine. In chapter 4, the magnetic-field-induced assembly of superparamagnetic cobalt nanoparticles both on solid substrates and at liquid-air interface was investigated. OA- and TOPO-coated Co NPs were synthesized via the thermolysis of cobalt carbonyl and dispersed into either hexane or toluene. The Co NP dispersion was dropped onto substrates (e.g., TEM grid, silicon wafer) and at liquid-air (water-air or ethylene glycol-air) interface. Due to the attractive dipolar interaction, 1-D chains formed in the presence of an external magnetic field. It is known that the concentration and the strength of the magnetic field can affect the assembly behavior of superparamagnetic Co NPs. Therefore, the influence of these two parameters on the morphology of the assemblies was studied. The formed 1-D chains were shorter and flexible at either lower concentration of the Co NP dispersion or lower strength of the external magnetic field due to thermal fluctuation. However, by increasing either the concentration of the NP dispersion or the strength of the applied magnetic field, these chains became longer, thicker and straighter. The reason could be that a high concentration led to a high fraction of short dipolar chains, and their interaction resulted in longer and thicker chains under applied magnetic field. On the other hand, when the magnetic field increased, the induced moments of the magnetic nanoparticles became larger, which dominated over the thermal fluctuation. Thus, the formed short chains connected to each other and grew in length. Thicker chains were also observed through chain-chain interaction. Furthermore, the induced moments of the NPs tended to direct into one direction with increased magnetic field, thus the chains were straighter. In comparison between the assembly on substrates, at water-air interface and at ethylene glycol-air interface, the assembly of Co NPs in hexane dispersion at ethylene glycol-air interface showed the most regular and homogeneous chain structures due to the better spreading of the dispersion on ethylene glycol subphase than on water subphase and substrates. The magnetic-field-induced assembly of superparamagnetic nanoparticles could provide a powerful approach for applications in data storage and electronic devices. Chapter 5 presented the synthesis of superparamagnetic and ferromagnetic cobalt nanoparticles through a dual-stage thermolysis of cobalt carbonyl (Co2(CO)8) by using polystyrene as surfactant. The amine end-functionalized polystyrene surfactants with different molecular weight were prepared via atom transfer radical polymerization technique. The molecular weight determination of polystyrene was conducted by gel permeation chromatography (GPC) and matrix-assisted laser desorption/ionization time-of-flight (MALDI-ToF) mass spectrometry techniques. The results showed that, when the molecular weight distribution is low (Mw/Mn < 1.2), the measurement by GPC and MALDI-ToF MS provided nearly similar results. For example, the molecular weight of 10600 Da was obtained by MALDI-ToF MS, while GPC gave 10500 g/mol (Mw/Mn = 1.17). However, if the polymer is poly distributed, MALDI-ToF MS cannot provide an accurate value. This was exemplified for a polymer with a molecular weight of 3130 Da measured by MALDI-TOF MS, while GPC showed 2300 g/mol (Mw/Mn = 1.38). The size, size distribution and magnetic properties of the hybrid particles were different by changing either the molecular weight or concentration of the polymer surfactants. The analysis from TEM characterization showed that the size of cobalt nanoparticles stabilized with polystyrene of lower molecular weight (Mn = 2300 g/mol) varied from 12-22 nm, while the size with middle (Mn = 4500 g/mol) and higher molecular weight (Mn = 10500 g/mol) of polystyrene-coated cobalt nanoparticles showed little change. Magnetic measurements exhibited that the small cobalt particles (12 nm) were superparamagnetic, while larger particles (21 nm) were ferromagnetic and assembled into 1-D chains. The grafting density calculated from thermogravimetric analysis showed that a higher grafting density of polystyrene was obtained with lower molecular weight (Mn = 2300 g/mol) than those with higher molecular weight (Mn = 10500 g/mol). Due to the larger steric hindrance, polystyrene with higher molecular weight cannot form a dense shell on the surface of the nanoparticles, which resulted in a lower grafting density. Wide angle X-ray scattering measurements revealed the epsilon cobalt crystalline phases of both superparamagnetic Co NPs coated with polystyrene (Mn = 2300 g/mol) and ferromagnetic Co NPs coated with polystyrene (Mn = 10500 g/mol). Furthermore, a stability study showed that PS-Co NPs prepared with higher polymer concentration and polymer molecular weight exhibited a better stability.},
  language  = {en}
}
@phdthesis{Lama2018,
  author    = {Lama, Sandy M. G.},
  title     = {Functionalization of Porous Carbon Materials with Heteroatoms and Application as Supports in Industrial Heterogeneous Catalysis},
  url       = {http://nbn-resolving.de/urn:nbn:de:kobv:517-opus4-415797},
  school      = {Universit{\"a}t Potsdam},
  pages     = {124},
  year      = {2018},
  abstract  = {Due to a challenging population growth and environmental changes, a need for new routes to provide required chemicals for human necessities arises. An effective solution discussed in this thesis is industrial heterogeneous catalysis. The development of an advanced industrial heterogeneous catalyst is investigated herein by considering porous carbon nano-material as supports and modifying their surface chemistry structure with heteroatoms. Such modifications showed a significant influence on the performance of the catalyst and provided a deeper insight regarding the interaction between the surface structure of the catalyst and the surrounding phase. This thesis contributes to the few present studies about heteroatoms effect on the catalyst performance and emphasizes on the importance of understanding surface structure functionalization in a catalyst in different phases (liquid and gaseous) and for different reactions (hydrogenolysis, oxidation, and hydrogenation/ polymerization). Herein, the heteroatoms utilized for the modifications are hydrogen (H), oxygen (O), and nitrogen (N). The heteroatoms effect on the metal particle size, on the polarity of the support/ the catalyst, on the catalytic performance (activity, selectivity, and stability), and on the interaction with the surrounding phase has been explored. First hierarchical porous carbon nanomaterials functionalized with heteroatoms (N) is synthesized and applied as supports for nickel nanoparticles for hydrogenolysis process of kraft lignin in liquid phase. This reaction has been performed in batch and flow reactors for three different catalysts, two of comparable hierarchical porosity, yet one is modified with N and the other is not, and a third is a prepared catalyst from a commercial carbon support. The reaction production and analyses show that the catalysts with hierarchical porosity perform catalytically much better than in presence of a commercial carbon support with lower surface area. Moreover, the modification with N-heteroatoms enhanced the catalytic performance because the heteroatom modified porous carbon material with nickel nanoparticles catalyst (Ni-NDC) performed highest among the other catalysts. In the flow reactor, Ni-NDC selectively degraded the ether bonds (β-O-4) in kraft lignin with an activity of 2.2 x10^-4 mg lignin mg Ni-1 s-1 for 50 h at 350°C and 3.5 mL min-1 flow, providing ~99 \% conversion to shorter chained chemicals (mainly guaiacol derivatives). Then, the functionalization of carbon surface was further studied in selective oxidation of glucose to gluconic acid using < 1 wt. \% of gold (Au) deposited on the previously-mentioned synthesized carbon (C) supports with different functionalities (Au-CGlucose, Au-CGlucose-H, Au-CGlucose-O, Au-CGlucoseamine). Except for Au-CGlucose-O, the other catalysts achieved full glucose conversion within 40-120 min and 100\% selectivity towards gluconic acid with a maximum activity of 1.5 molGlucose molAu-1 s-1 in an aqueous phase at 45 °C and pH 9. Each heteroatom influenced the polarity of the carbon differently, affecting by that the deposition of Au on the support and thus the activity of the catalyst and its selectivity. The heteroatom effect was further investigated in a gas phase. The Fischer-Tropsch reaction was applied to convert synthetic gas (CO and H2) to short olefins and paraffins using surface-functionalized carbon nanotubes (CNTs) with heteroatoms as supports for ion (Fe) deposition in presence and absence of promoters (Na and S). The results showed the promoted Fe-CNT doped with nitrogen catalyst to be stable up to 180 h and selective to the formation of olefins (~ 47 \%) and paraffins (~6 \%) with a conversion of CO ~ 92 \% at a maximum activity of 94 *10^-5 mol CO g Fe-1 s-1. The more information given regarding this topic can open wide range of applications not only in catalysis, but in other approaches as well. In conclusion, incorporation of heteroatoms can be the next approach for an advanced industrial heterogeneous catalyst, but also for other applications (e.g. electrocatalysis, gas adsorption, or supercapacitors).},
  language  = {en}
}