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Natural light harvesting as well as optoelectronic and photovoltaic devices depend on efficient transport of energy following photoexcitation. Using common spectroscopic methods, however, it is challenging to discriminate one-exciton dynamics from multi-exciton interactions that arise when more than one excitation is present in the system. Here we introduce a coherent two-dimensional spectroscopic method that provides a signal only in case that the presence of one exciton influences the behavior of another one. Exemplarily, we monitor exciton diffusion by annihilation in a perylene bisimide-based J-aggregate. We determine quantitatively the exciton diffusion constant from exciton–exciton-interaction 2D spectra and reconstruct the annihilation-free dynamics for large pump powers. The latter enables for ultrafast spectroscopy at much higher intensities than conventionally possible and thus improves signal-to-noise ratios for multichromophore systems; the former recovers spatio–temporal dynamics for a broad range of phenomena in which exciton interactions are present.
In order to shrink the size of semiconductor devices and improve their
efficiency at the same time, silicon-based semiconductor devices have
been engineered, until the material almost reaches its performance
limits. As the candidate to be used next in semiconducting devices,
single-wall carbon nanotubes show a great potential due to their
promise of increased device efficiency and their high charge carrier
mobilities in the nanometer size active areas. However, there are
material based problems to overcome in order to imply SWNTs in the
semiconductor devices. SWNTs tend to aggregate in bundles and it is
not trivial to obtain an electronically or chirally homogeneous SWNT
dispersion and when it is done, a homogeneous thin film needs to be
produced with a technique that is practical, easy and scalable. This
work was aimed to solve both of these problems.
In the first part of this study, six different polymers, containing
fluorene or carbazole as the rigid part and bipyridine, bithiophene or
biphenyl as the accompanying copolymer unit, were used to selectively
disperse semiconducting SWNTs. With the data obtained from
absorption and photoluminescence spectroscopy of the corresponding
dispersions, it was found out that the rigid part of the copolymer plays a
primary role in determining its dispersion efficiency and electronic
sorting ability. Within the two tested units, carbazole has a higher π
electron density. Due to increased π−π interactions, carbazole
containing copolymers have higher dispersion efficiency. However, the
electronic sorting ability of fluorene containing polymers is superior.
Chiral selection of the polymers in the dispersion is not directly
foreseeable from the selection of backbone units. At the end, obtaining a monochiral dispersion is found to be highly dependent on the used raw
material in combination to the preferred polymer.
Next, one of the best performing polymers due to high chirality
enrichment and electronic sorting ability was chosen in order to
disperse SWNTs. Thin films of varying thickness between 18 ± 5 to
755o±o5 nm were prepared using vacuum filtration wet transfer method
in order to analyze them optically and electronically.
The scalability and efficiency of the integrated thin film production
method were shown using optical, topographical and electronic
measurements. The relative photoluminescence quantum yield of the
radiative decay from the SWNT thin films was found to be constant for
the thickness scale. Constant roughness on the film surface and linearly
increasing concentration of SWNTs were also supporting the scalability
of this thin film production method. Electronic measurements on bottom
gate top contact transistors have shown an increasing charge carrier
mobility for linear and saturation regimes. This was caused by the
missing normalization of the mobility for the thickness of the active
layer. This emphasizes the importance of considering this dimension for
comparison of different field effect transistor mobilities.
Theory predicts peculiar features for excited-state dynamics in one dimension (1D) that are difficult to be observed experimentally. Single-walled carbon nanotubes (SWNTs) are an excellent approximation to 1D quantum confinement, due to their very high aspect ratio and low density of defects. Here we use ultrafast optical spectroscopy to probe photogenerated charge-carriers in (6,5) semiconducting SWNTs. We identify the transient energy shift of the highly polarizable S\(_{33}\) transition as a sensitive fingerprint of charge-carriers in SWNTs. By measuring the coherent phonon amplitude profile we obtain a precise estimate of the Stark-shift and discuss the binding energy of the S\(_{33}\) excitonic transition. From this, we infer that charge-carriers are formed instantaneously (<50 fs) even upon pumping the first exciton, S\(_{11}\). The decay of the photogenerated charge-carrier population is well described by a model for geminate recombination in 1D.
Fluorogenic RNA aptamers are synthetic functional RNAs that specifically bind and activate conditional fluorophores. The Chili RNA aptamer mimics large Stokes shift fluorescent proteins and exhibits high affinity for 3,5-dimethoxy-4-hydroxybenzylidene imidazolone (DMHBI) derivatives to elicit green or red fluorescence emission. Here, we elucidate the structural and mechanistic basis of fluorescence activation by crystallography and time-resolved optical spectroscopy. Two co-crystal structures of the Chili RNA with positively charged DMHBO+ and DMHBI+ ligands revealed a G-quadruplex and a trans-sugar-sugar edge G:G base pair that immobilize the ligand by π-π stacking. A Watson-Crick G:C base pair in the fluorophore binding site establishes a short hydrogen bond between the N7 of guanine and the phenolic OH of the ligand. Ultrafast excited state proton transfer (ESPT) from the neutral chromophore to the RNA was found with a time constant of 130 fs and revealed the mode of action of the large Stokes shift fluorogenic RNA aptamer.
The work proposes possible designs of active regions for a mode-locked interband cascade laser emitting in the mid infrared. For that purpose we investigated the electronic structure properties of respectively modified GaSb-based type II W-shaped quantum wells, including the effect of external bias in order to simultaneously fulfil the requirements for both the absorber as well as the gain sections of a device. The results show that introducing multiple InAs layers in type II InAs/GaInSb quantum wells or introducing a tensely-strained GaAsSb layer into “W-shaped” type II QWs offers significant difference in optical transitions’ oscillator strengths (characteristic lifetimes) of the two oppositely polarized parts of such a laser, being promising for utilization in mode-locked devices.
Die vorliegende Arbeit befasste sich mit dem Spin- und dem damit eng verbundenen Polarisationszustand von Ladungsträgern in CdSe/ZnSe Quantenpunkten. II-VI Materialsysteme können in geeigneter Weise mit dem Nebengruppenelement Mangan gemischt werden. Diese semimagnetischen Nanostrukturen weisen eine Vielzahl von charakteristischen optischen und elektrischen Besonderheiten auf. Verantwortlich dafür ist eine Austauschwechselwirkung zwischen dem Spin optisch erzeugter Ladungsträger und den 3d Elektronen der Mn Ionen. Im Rahmen dieser Arbeit erfolgte die Adressierung gezielter Spinzustände durch optische Anregung der Ladungsträger. Die Besetzung unterschiedlicher Spinzustände konnte durch Detektion des Polarisationsgrades der emittierten Photolumineszenz (PL) bestimmt werden. Dabei kamen verschiedene optische Methoden wie zeitaufgelöste und zeitintegrierte PL-Spektroskopie sowie Untersuchungen in Magnetfeldern zum Einsatz.
Die vorliegende Arbeit beschäftigt sich mit optischen Untersuchungen an niederdimensionalen III/V-Halbleiterstrukturen. Dabei werden zunächst im ersten Teil selbst-organisiert gewachsene Nanodrähte aus InP und GaN bezüglich ihrer Oberflächen- und Kristallqualität charakterisiert. Dies ist besonders im Hinblick auf zukünftige opto- und nanoelektronische Bauteile von Interesse. Der zweite, grundlagenorientierte Teil der Arbeit ist im Bereich der Quantenoptik angesiedelt und widmet sich magneto-optischen Studien zur Licht-Materie Wechselwirkung in Quantenpunkt-Mikroresonator-Systemen im Regime der starken Kopplung. Oberflächen-Untersuchungen an Halbleiter-Nanodrähten Bei diesem Teilaspekt der vorliegenden Arbeit stehen Untersuchungen von Halbleiter-Nanodrähten mittels zeitintegrierter und zeitaufgelöster Photolumineszenz (PL)-Spektroskopie im Vordergrund. Diese eindimensionalen Nanostrukturen bieten eine vielversprechende Perspektive für die weitere Miniaturisierung in der Mikroelektronik. Da konventionelle Strukturierungsverfahren wie die optische Lithographie zunehmend an physikalische und technologische Grenzen stoßen, sind selbstorganisierte Wachstumsprozesse hierbei von besonderem Interesse. Bei Nanodrähten besteht darüber hinaus konkret noch die Möglichkeit, über ein gezieltes axiales und radiales Wachstum von Heterostrukturen bereits bei der Herstellung komplexere Funktionalitäten einzubauen. Auf Grund ihres großen Oberfläche-zu-Volumen Verhältnisses sind die elektronischen und optischen Eigenschaften der Nanodrähte extrem oberflächensensitiv, was vor allem im Hinblick auf zukünftige Anwendungen im Bereich der Mikro- oder Optoelektronik sowie der Sensorik von essentieller Bedeutung ist. Zur näheren Untersuchung der Oberflächeneigenschaften von Nanodrähten eignet sich die optische Spektroskopie besonders, da sie als nicht-invasive Messmethode ohne aufwändige Probenpräparation schnell nützliche Informationen liefert, die zum Beispiel in der Optimierung des Herstellungsprozesses eingesetzt werden können. Quantenoptik an Halbleiter-Mikrokavitäten Der zweite Teil dieser Arbeit widmet sich der Licht-Materie-Wechselwirkung in Quantenpunkt-Mikroresonator-Systemen. Dabei ist das Regime der starken Kopplung zwischen Emitter und Resonator, auch im Hinblick auf mögliche zukünftige Anwendungen in der Quanteninformationsverarbeitung, von besonderem Interesse. Diese Mikroresonator-Türmchen, die auf planaren AlAs/GaAs-Mikroresonatoren mit InGaAs Quantenpunkten in der aktiven Schicht basieren, wurden mittels zeitintegrierter und zeitaufgelöster Mikro-PL-Spektroskopie in einem äußeren magnetischen Feld in Faraday-Konfiguration untersucht. Grundlegende Untersuchungen von Quantenpunkten im Magnetfeld Zunächst wurden InxGa(1−x)As-Quantenpunkte mit unterschiedlichem In-Gehalt (x=30%, 45% und 60%) magneto-optisch untersucht. Aufgrund der größeren Abmessungen weisen die Quantenpunkte mit 30% In-Anteil auch hohe Oszillatorstärken auf, was sie besonders für Experimente zur starken Kopplung auszeichnet. Unter dem Einfluss des Magnetfeldes zeigte sich ein direkter Zusammenhang zwischen der lateralen Ausdehnung der Quantenpunkte und ihrer diamagnetischen Verschiebung. Starke Kopplung im magnetischen Feld Neben der Möglichkeit, das Resonanzverhalten über das externe Magnetfeld zu kontrollieren, zeigte sich eine Korrelation zwischen der Kopplungsstärke und dem magnetischen Feld, was auf eine Verringerung der Oszillatorstärke im Magnetfeld zurückgeführt werden konnte. Diese steht wiederum im Zusammenhang mit einer Einschnürung der Wellenfunktion des Exzitons durch das angelegte Feld. Dieser direkte Einfluss des Magnetfeldes auf die Oszillatorstärke erlaubt eine in situ Variation der Kopplungsstärke. Photon-Photon-Wechselwirkung bei der starken Kopplung im Magnetfeld Nach der Demonstration der starken Kopplung zwischen entarteten Exziton- und Resonatormoden im Magnetfeld, wurden im weiteren Verlauf Spin-bezogene Kopplungseffekte im Regime der starken Kopplung untersucht. Es ergaben sich im Magnetfeld unter Variation der Temperatur zwei Bereiche der Wechselwirkung zwischen den einzelnen Komponenten von Resonator- und Exzitonenmode. Von besonderem Interesse ist dabei eine beobachtete indirekte Wechselwirkung zwischen den beiden photonischen Moden im Moment der Resonanz, die durch die exzitonische Mode vermittelt wird. Diese sogenannte Spin-vermittelte Photon-Photon-Kopplung stellt ein Bindeglied zwischen eigentlich unabhängigen photonischen Moden über den Spinzustand eines Exzitons dar.
The maximum efficiency of any solar cell can be evaluated in terms of its corresponding ability to emit light. We herein determine the important figure of merit of radiative efficiency for Methylammonium Lead Iodide perovskite solar cells and, to put in context, relate it to an organic photovoltaic (OPV) model device. We evaluate the reciprocity relation between electroluminescence and photovoltaic quantum efficiency and conclude that the emission from the perovskite devices is dominated by a sharp band-to-band transition that has a radiative efficiency much higher than that of an average OPV device. As a consequence, the perovskite have the benefit of retaining an open circuit voltage ~0.14 V closer to its radiative limit than the OPV cell. Additionally, and in contrast to OPVs, we show that the photoluminescence of the perovskite solar cell is substantially quenched under short circuit conditions in accordance with how an ideal photovoltaic cell should operate.
Light-induced excitation of matter proceeds within femtoseconds, resulting in excited states. Originating from these states chemical reaction mechanisms, like isomerization or bond formation, set in. Photophysical mechanisms like energy distribution and excitonic delocalization also occur. Thus, the reaction scheme has to be disentangled by assessing the importance of each process. Spectroscopic methods based on fs laser pulses have emerged as a versatile tool to study these reactions. Within this thesis time-resolved experiments with fs laser pulses on various molecular systems were performed. Novel photosystems, with possible applications ranging from ultrathin molecular wires to molecular switches, were extensively characterized. To resolve the complex kinetics of the investigated systems, time-resolved techniques had to be newly developed. By combining a visible excitation pulse pair with an additional pulse and a continuum probe electronic triggered-exchange two-dimensional spectroscopy (TE2D) was demonstrated for the first time. This goal was accomplished by combining a three-color transient-absorption setup with a pulse shaper. Hence, 2D spectroscopy with a continuum probe was also implemented. Using these methods two different molecular systems in solution were characterized in a comprehensive manner. (ZnTPP)2, a directly beta,beta’-linked Zn-metallated bisporphyrin, and a spiropyran-merocyanine photosystem, 6,8-dinitro BIPS, were characterized. (ZnTPP)2 is a homodimer, featuring strong excitonic effects. These manifest themselves in a twofold splitting of the Soret band (S2). 6,8-Dinitro BIPS exists in one of two possible conformations. The ring closed spiropyran absorbs only in the UV, while the ring open merocyanine also absorbs in the visible. For both molecular systems photodynamics upon illumination were monitored using transient-absorption. However, the obtained results were ambiguous, necessitating more complex methods. In the case of (ZnTPP)2 first the monomeric building block was characterized. There, population transfer from the S2 state into S1 within 2 ps was identified. Afterwards, intersystem crossing proceeds within 2 ns. For (ZnTPP)2 similar pathways were found, albeit the relaxation is faster. The intersystem crossing with 1.5 ns was not only indirectly deduced but directly measured by probing in the NIR spectral range. The excitonic influence of was investigated by coherent 2D spectroscopy in the Soret band. Population transfer within S2 was directly visualized on a time-scale of 100 fs. Calculation of the 2D spectra of a simple homodimer confirmed the results. After this analysis of the distinct excitonic character, this molecule may serve as a building block for larger porphyrin arrays with applications ranging from asymmetric catalysis over biomimicry of electron-transfer to organic optical devices. The second photosystem was the molecular switch 6,8-dinitro BIPS, existing in two conformations. Merocyanine is the more stable form in thermal equilibrium. Transient-absorption measurements uncovered that the sample consisted of a mixture of two merocyanine isomers, referred to as TTC and TTT. However, both isomers are capable of ring-closure forming spiropyran. The remaining excited molecules return to the ground state radiatively. Conducting 2D measurements utilizing a continuum probe the differing photochemistry of both isomers was examined in a single measurement. No isomerization between these conformations was detected. Therefore, 6,8-dinitro BIPS performs a concerted switching without long-living intermediates. This was confirmed by a pump-repump-probe scan. 6,8-DinitroBIPS can be closed by visible and opened by UV pulses using subsequent pulses and vice versa. These mechanisms via singlet pathways satisfy an important criterion for a unimolecular switching device. A second pump-repump-probe experiment showed that the sample is ionized, resulting in a merocyanine radical cation, when the first excited state is resonantly excited. Furthermore, by implementing TE2Dspectroscopy, it was elucidated that only TTC was ionized. Taking all this into account new techniques were developed and complex molecular systems were characterized within this thesis. Deeper insight into the photodynamics of (ZnTPP)2and 6,8-dinitro BIPS was gained by adapting transient absorption for the NIR spectral range, constructing a 2D setup in pump-probe geometry, and combining it with multipulse excitation to coherent TE2D. All techniques solved the questions for which they were constructed, but they are not limited to these cases. Especially TE2D opens new roads in photochemistry. By connecting reactant, product and the corresponding intermediates, a chemical reaction can be tracked through all stages, making unambiguous identification of the reactive states feasible. Thus, fundamental insight into the photochemistry of molecular compounds is gained.