@phdthesis{Rietze2020,
  author    = {Rietze, Clemens},
  title     = {Optimierung und Analyse von molekularen Schaltern in komplexen Umgebungen: thermische Stabilit{\"a}t, Auslesbarkeit und Schaltbarkeit},
  doi       = {10.25932/publishup-45959},
  url       = {http://nbn-resolving.de/urn:nbn:de:kobv:517-opus4-459594},
  school      = {Universit{\"a}t Potsdam},
  pages     = {131},
  year      = {2020},
  abstract  = {Seit Jahrzehnten stellen die molekularen Schalter ein wachsendes Forschungsgebiet dar. Im Rahmen dieser Dissertation stand die Verbesserung der thermischen Stabilit{\"a}t, der Auslesbarkeit und Schaltbarkeit dieser molekularen Schalter in komplexen Umgebungen mithilfe computergest{\"u}tzter Chemie im Vordergrund. Im ersten Projekt wurde die Kinetik der thermischen E → Z-Isomerisierung und die damit verbundene thermische Stabilit{\"a}t eines Azobenzol-Derivats untersucht. Daf{\"u}r wurde Dichtefunktionaltheorie (DFT) in Verbindung mit der Eyring-Theorie des {\"U}bergangszustandes (TST) angewendet. Das Azobenzol-Derivat diente als vereinfachtes Modell f{\"u}r das Schalten in einer komplexen Umgebung (hier in metallorganischen Ger{\"u}sten). Es wurden thermodynamische und kinetische Gr{\"o}ßen unter verschiedenen Einfl{\"u}ssen berechnet, wobei gute {\"U}bereinstimmungen mit dem Experiment gefunden wurden. Die hier verwendete Methode stellte einen geeigneten Ansatz dar, um diese Gr{\"o}ßen mit angemessener Genauigkeit vorherzusagen. Im zweiten Projekt wurde die Auslesbarkeit der Schaltzust{\"a}nde in Form des nichtlinearen optischen (NLO) Kontrastes f{\"u}r die Molek{\"u}lklasse der Fulgimide untersucht. Die daf{\"u}r ben{\"o}tigten dynamischen Hyperpolarisierbarkeiten unter Ber{\"u}cksichtigung der Elektronenkorrelation wurden mittels einer etablierten Skalierungsmethode berechnet. Es wurden verschiedene Fulgimide analysiert, wobei viele experimentelle Befunde best{\"a}tigt werden konnten. Dar{\"u}ber hinaus legte die theoretische Vorhersage f{\"u}r ein weiteres System nahe, dass insbesondere die Erweiterung des π-Elektronensystems ein vielversprechender Ansatz zur Verbesserung von NLO-Kontrasten darstellt. Die Fulgimide verf{\"u}gen somit {\"u}ber n{\"u}tzliche Eigenschaften, sodass diese in Zukunft als Bauelemente in photonischen und optoelektronischen Bereichen Anwendungen finden k{\"o}nnten. Im dritten Projekt wurde die E → Z-Isomerisierung auf ein quantenmechanisch (QM) behandeltes Dimer mit molekularmechanischer (MM) Umgebung und zwei Fluorazobenzol-Monomeren durch Molek{\"u}ldynamik simuliert. Dadurch wurde die Schaltbarkeit in komplexer Umgebung (hier selbstorgansierte Einzelschichten = SAMs) bzw. von Azobenzolderivaten analysiert. Mit dem QM/MM Modell wurden sowohl Van-der-Waals-Interaktionen mit der Umgebung als auch elektronische Kopplung (nur zwischen QM-Molek{\"u}len) ber{\"u}cksichtigt. Dabei wurden systematische Untersuchungen zur Packungsdichte durchgef{\"u}hrt. Es zeigte sich, dass bereits bei einem Molek{\"u}labstand von 4.5 {\AA} die Quantenausbeute (prozentuale Anzahl erfolgreicher Schaltprozesse) des Monomers erreicht wird. Die gr{\"o}ßten Quantenausbeuten wurden f{\"u}r die beiden untersuchten Fluorazobenzole erzielt. Es wurden die Effekte des Molek{\"u}labstandes und der Einfluss von Fluorsubstituenten auf die Dynamik eingehend untersucht, sodass der Weg f{\"u}r darauf aufbauende Studien geebnet ist.},
  language  = {de}
}
@phdthesis{Ksianzou2010,
  author    = {Ksianzou, Viachaslau},
  title     = {Second-order nonlinear optical interactions and cascading effects in thinorganic films},
  url       = {http://nbn-resolving.de/urn:nbn:de:kobv:517-opus-49186},
  school      = {Universit{\"a}t Potsdam},
  year      = {2010},
  abstract  = {The presented work describes new concepts of fast switching elements based on principles of photonics. The waveguides working in visible and infra-red ranges are put in a basis of these elements. And as materials for manufacturing of waveguides the transparent polymers, dopped by molecules of the dyes possessing second order nonlinear-optical properties are proposed. The work shows how nonlinear-optical processes in such structures can be implemented by electro-optical and opto-optical control circuit signals. In this paper we consider the complete cycle of fabrication of several types of integral photonic elements. The theoretical analysis of high-intensity beam propagation in media with second-order optical nonlinearity is performed. Quantitative estimations of necessary conditions of occurrence of the nonlinear-optical phenomena of the second order taking into account properties of used materials are made. The paper describes the various stages of manufacture of the basic structure of the integrated photonics: a planar waveguide. Using the finite element method the structure of the electromagnetic field inside the waveguide in different modes was analysed. A separate part of the work deals with the creation of composite organic materials with high optical nonlinearity. Using the methods of quantum chemistry, the dependence of nonlinear properties of dye molecules from its structure were investigated in details. In addition, the paper discusses various methods of inducing of an optical nonlinearity in dye-doping of polymer films. In the work, for the first time is proposed the use of spatial modulation of nonlinear properties of waveguide according Fibonacci law. This allows involving several different nonlinear optical processes simultaneously. The final part of the work describes various designs of integrated optical modulators and switches constructed of organic nonlinear optical waveguides. A practical design of the optical modulator based on Mach-Zehnder interferometer made by a photolithography on polymer film is presented.},
  language  = {en}
}
@phdthesis{Koelsch2005,
  author    = {K{\"o}lsch, Patrick},
  title     = {Static and dynamic properties of soluble surfactants at the air/water interface},
  url       = {http://nbn-resolving.de/urn:nbn:de:kobv:517-opus-5716},
  school      = {Universit{\"a}t Potsdam},
  year      = {2005},
  abstract  = {Amphiphilic molecules contain a hydrophilic headgroup and a hydrophobic tail. The headgroup is polar or ionic and likes water, the tail is typically an aliphatic chain that cannot be accommodated in a polar environment. The prevailing molecular asymmetry leads to a spontaneous adsorption of amphiphiles at the air/water or oil/water interfaces. As a result, the surface tension and the surface rheology is changed. Amphiphiles are important tools to deliberately modify the interfacial properties of liquid interfaces and enable new phenomena such as foams which cannot be formed in a pure liquid. In this thesis we investigate the static and dynamic properties of adsorption layers of soluble amphiphiles at the air/water interface, the so called Gibbs monolayers. The classical way for an investigation of these systems is based on a thermodynamic analysis of the equilibrium surface tension as a function of the bulk composition in the framework of Gibbs theory. However, thermodynamics does not provide any structural information and several recent publications challenge even fundamental text book concepts. The experimental investigation faces difficulties imposed by the low surface coverage and the presence of dissolved amphiphiles in the adjacent bulk phase. In this thesis we used a suite of techniques with the sensitivity to detect less than a monolayer of molecules at the air-water interface. Some of these techniques are extremely complex such as infrared visible sum frequency generation (IR-VIS SFG) spectroscopy or second harmonic generation (SHG). Others are traditional techniques, such as ellipsometry employed in new ways and pushed to new limits. Each technique probes selectively different parts of the interface and the combination provides a profound picture of the interfacial architecture. The first part of the thesis is dedicated to the distribution of ions at interfaces. Adsorption layers of ionic amphiphiles serve as model systems allowing to produce a defined surface charge. The charge of the monolayer is compensated by the counterions. As a result of a complex zoo of interactions there will be a defined distribution of ions at the interface, however, its experimental determination is a big scientific challenge. We could demonstrate that a combination of linear and nonlinear techniques gives direct insights in the prevailing ion distribution. Our investigations reveal specific ion effects which cannot be described by classical Poisson-Boltzmann mean field type theories. Adsorption layer and bulk phase are in thermodynamic equilibrium, however, it is important to stress that there is a constant molecular exchange between adsorbed and dissolved species. This exchange process is a key element for the understanding of some of the thermodynamic properties. An excellent way to study Gibbs monolayers is to follow the relaxation from a non-equilibrium to an equilibrium state. Upon compression amphiphiles must leave the adsorption layer and dissolve in the adjacent bulk phase. Upon expansion amphiphiles must adsorb at the interface to restore the equilibrium coverage. Obviously the frequency of the expansion and compression cycles must match the molecular exchange processes. At too low frequencies the equilibrium is maintained at all times. If the frequency is too fast the system behaves as a monolayer of insoluble surfactants. In this thesis we describe an unique variant of an oscillating bubble technique that measures precisely the real and imaginary part of the complex dilational modulus E in a frequency range up to 500 Hz. The extension of about two decades in the time domain in comparison to the conventional method of an oscillating drop is a tremendous achievement. The imaginary part of the complex dilational modulus E is a consequence of a dissipative process which is interpreted as an intrinsic surface dilational viscosity. The IR-VIS SFG spectra of the interfacial water provide a molecular interpretation of the underlying dissipative process.},
  subject      = {Nichtlineare Optik},
  language  = {en}
}