@phdthesis{Koch2016, author = {Koch, Federico Juan}, title = {Structure-Dependent Ultrafast Relaxation Dynamics in Multichromophoric Systems}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-136306}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2016}, abstract = {Time-resolved spectroscopy allows for analyzing light-induced energy conversion and chromophore-chromophore interactions in molecular systems, which is a prerequisite in the design of new materials and for improving the efficiency of opto-electronic devices. To elucidate photo-induced dynamics of complex molecular systems, transient absorption (TA) and coherent two-dimensional (2D) spectroscopy were employed and combined with additional experimental techniques, theoretical approaches, and simulation models in this work. A systematic series of merocyanines, synthetically varied in the number of chromophores and subsitution pattern, attached to a benzene unit was investigated in cooperation with the group of Prof. Dr. Frank W{\"u}rthner at the University of W{\"u}rzburg. The global analysis of several TA experiments, and additional coherent 2D spectroscopy experiments, provided the basis to elaborate a relaxation scheme which was applicable for all merocyanine systems under investigation. This relaxation scheme is based on a double minimum on the excited-state potential energy surface. One of these minima is assigned to an intramolecular charge-transfer state which is stabilized in the bis- and tris-chromophoric dyes by chromphore-chromophore interactions, resulting in an increase in excited-state lifetime. Electro-optical absorption and density functional theory (DFT) calculations revealed a preferential chromophore orientation which compensates most of the dipole moment of the individual chromophores. Based on this structural assignment the conformationdependent exciton energy splitting was calculated. The linear absorption spectra of the multi-chromophoric merocyanines could be described by a combination of monomeric and excitonic spectra. Subsequently, a structurally complex polymeric squaraine dye was studied in collaboration with the research groups of Prof. Dr. Christoph Lambert and Prof. Dr. Roland Mitric at the University of W{\"u}rzburg. This polymer consists of a superposition of zigzag and helix structures depending on the solvent. High-level DFT calculations confirmed the previous assignment that zigzag and helix structures can be treated as J- and H-aggregates, respectively. TA experiments revealed that in dependence on the solvent as well as the excitation energy, ultrafast energy transfer within the squaraine polymer proceeds from initially excited helix segments to zigzag segments or vice versa. Additionally, 2D spectroscopy confirmed the observed sub-picosecond dynamics. In contrast to other conjugated polymers such as MEH-PPV, which is investigated in the last chapter, ultrafast energy transfer in squaraine polymers is based on the matching of the density of states between donor and acceptor segments due to the small reorganization energy in cyanine-like chromophores. Finally, the photo-induced dynamics of the aggregated phase of the conjugated polymer MEH-PPV was investigated in cooperation with the group of Prof. Dr. Anna K{\"o}hler at the University of Bayreuth. Our collaborators had previously described the aggregation of MEH-PPV upon cooling by the formation of so-called HJ-aggregates based on exciton theory. By TA measurements and by making use of an affiliated band analysis distinct relaxation processes in the excited state and to the ground state were discriminated. By employing 2D spectroscopy the energy transfer between different conjugated segments within the aggregated polymer was resolved. The initial exciton relaxation within the aggregated phase indicates a low exciton mobility, in contrast to the subsequent energy transfer between different chromophores within several picoseconds. This work contributes by its systematic study of structure-dependent relaxation dynamics to the basic understanding of the structure-function relationship within complex molecular systems. The investigated molecular classes display a high potential to increase efficiencies of opto-electronic devices, e.g., organic solar cells, by the selective choice of the molecular morphology.}, subject = {Femtosekundenspektroskopie}, language = {en} } @phdthesis{SeligParthey2012, author = {Selig-Parthey, Ulrike}, title = {Methods of Nonlinear Femtosecond Spectroscopy in the Visible and Ultraviolet Regime and their Application to Coupled Multichromophore Systems}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-74356}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2012}, abstract = {Time-resolved spectroscopic studies of energy transfer between molecules in solution form a basis for both, our understanding of fundamental natural processes like photosynthesis as well as directed synthetic approaches to optimize organic opto-electronic devices. Here, coherent two-dimensional (2D) spectroscopy opens up new possibilities, as it reveals the correlation between absorption and emission frequency and hence the full cause-and-effect chain. In this thesis two optical setups were developed and implemented, permitting the recording of electronic 2D spectra in the visible and in the hitherto unexplored ultraviolet spectral range. Both designs rely on the exclusive manipulation of beam pairs, which reduces the signal modulation to the difference between the transition frequency of the system and the laser frequency. Thus - as has been shown experimentally and theoretically - the timing precision as well as mechanical stability requirements are greatly reduced, from fractions of the oscillation period of the exciting light wave to fractions of the pulse duration. Two-dimensional spectroscopy and femtosecond transient absorption (TA) as well as different theoretical approaches and simulation models were then applied to coupled multichromophore systems of increasing complexity. Perylene bisimide-perylene monoimide dyads were investigated in cooperation with Prof. Dr. Frank W{\"u}rthner and Prof. Dr. Bernd Engels at the University of W{\"u}rzburg. In these simplest systems studied, global analysis of six different TA experiments unequivocally revealed an ultrafast interchromophoric energy transfer in the 100 fs range. Comparison between the obtained transfer rates and the predictions of F{\"o}rster theory suggest a breakdown of this point-transition-dipole-based picture at the donor-acceptor distances realized in our compounds. Furthermore, a model including conformational changes and an interchromophoric charge transfer has been derived to consistently describe the observed pico- to nanosecond dynamics and fluorescence quantum yields. A second collaboration with Prof. Dr. Gregory Scholes (University of Toronto, Canada) and Prof. Dr. Paul Burn (University of Queensland, Australia) addressed the photophysics of a series of uorene-carbazole dendrimers. Here, a combination of 2D-UV spectroscopy and femtosecond ansiotropy decay experiments revealed the initial delocalization of the excited state wave function that saturates with the second generation. In room temperature solution, disorder-induced localization takes place on the time scales comparable to our instrument response, i.e. 100 fs, followed by energy transfer via incoherent hopping processes. Lastly, in tubular zinc chlorin aggregates, semi-synthetic analogues of natural lightharvesting antennae that had again been synthesized in the group of Prof. Dr. Frank W{\"u}rthner, the interchromophoric coupling is so strong that coherently coupled domains prevail even at room temperature. From an analysis of intensity-dependent TA measurements the dimensions of these domains, the exciton delocalization length, could be determined to span 5-20 monomers. In addition, 2D spectra uncovered efficient energy transfer between neighboring domains, i.e. ultrafast exciton diffusion.}, subject = {Femtosekundenspektroskopie}, language = {en} }