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Prof. Dr. rer. nat. habil. Katharina Krischer

Photo von Prof. Katharina Krischer.
Telefon
+49 89 289-12535
Raum
PH: 3087
E-Mail
krischer@tum.de
frauenbeauftragte@ph.tum.de (Stellvertretende Frauenbeauftragte des Physik-Departments)
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Homepage
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Arbeitsgruppe
Chemische Physik fern des Gleichgewichts
Funktionen

Lehrveranstaltungen und Termine

Ausgeschriebene Angebote für Abschlussarbeiten

Frequenzcluster und intrinsiches Entrainment in diffusiv gekoppelten oscillatorischen Systemen

In experiments on the oscillatory electrodissolution of Si wafers in fluoride containing electrolytes we observed a variety of peculiar nonlinear phenomena, whose importance goes far beyond our specific experimental systems. Among them are frequency clusters, i.e. the spontaneous formation of two or more regions on the electrode surface that oscillate with different frequencies, as well as patterns that emerge through internal entrainment. In the master thesis, the conditions under which these two types of collective oscillation modes emerge, should be further investigated both experimentally and with proto-typical equations. The aim of the master thesis is to understand the conditions under which such patterns might form from a nonlinear dynamics point of view.

geeignet als
  • Masterarbeit Physik der kondensierten Materie
  • Masterarbeit Biophysik
  • Masterarbeit Applied and Engineering Physics
Themensteller(in): Katharina Krischer
Photoelektrochemische Reduktion von CO2 zu solaren Brennstoffen an Au/Cu nanostrukturierten MIS (Metall/Isolator/Halbleiter)-Übergängen

The photoelectrochemical convrson of CO2 to solar fuels is a promising way to address the challenge of renewable energy provision in future. Depending on the catalyst and the electrochemical environment, the products of the electrochemical CO2 reduction reaction are diverse. The aim of this master thesisis to investigate the influence of different systems parameters (electrolyte composition, structure geometries and compositions) on the electrochemical and catalytic behavior of the nanostrucutred MIS interfaces.

geeignet als
  • Masterarbeit Physik der kondensierten Materie
  • Masterarbeit Applied and Engineering Physics
Themensteller(in): Katharina Krischer
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