540 Chemie und zugeordnete Wissenschaften
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- time-dependent density functional theory (1)
- time-resolved optical spectroscopy (1)
- titanium (1)
- transient absorption spectroscopy (1)
- transiente Absorption (1)
- transiente Absorptionsspektroskopie (1)
- transition metal complexes (1)
- trap (1)
- truxenone (1)
- van der Waals Clustern (1)
- van der Waals clusters (1)
- verzögerte Fluoreszenz (1)
- vibrational spectroscopy (1)
- vier Wellen Mischen Spektroskopie (1)
- vinylidene complexes (1)
- wallpainting (1)
- warhead (1)
- weak coupling regime (1)
- xylylene (1)
- zeitabhängige Dichtefunktionaltheorie (1)
- zeitaufgelöste Spektroskopie (1)
- Übergangszustand (1)
- ätherische Öle (1)
- π-complex (1)
- π-conjugated systems (1)
Institute
- Institut für Physikalische und Theoretische Chemie (116) (remove)
Sonstige beteiligte Institutionen
ResearcherID
- B-1911-2015 (1)
- N-3741-2015 (1)
Besides their widespread use in coordination chemistry, 2,2’‐bipyridines are known for their ability to undergo cis–trans conformational changes in response to metal ions and acids, which has been primarily investigated at the molecular level. However, the exploitation of such conformational switching in self‐assembly has remained unexplored. In this work, the use of 2,2’‐bipyridines as acid‐responsive conformational switches to tune supramolecular polymerization processes has been demonstrated. To achieve this goal, we have designed a bipyridine‐based linear bolaamphiphile, 1, that forms ordered supramolecular polymers in aqueous media through cooperative aromatic and hydrophobic interactions. Interestingly, addition of acid (TFA) induces the monoprotonation of the 2,2’‐bipyridine moiety, leading to a switch in the molecular conformation from a linear (trans) to a V‐shaped (cis) state. This increase in molecular distortion along with electrostatic repulsions of the positively charged bipyridine‐H\(^{+}\) units attenuate the aggregation tendency and induce a transformation from long fibers to shorter thinner fibers. Our findings may contribute to opening up new directions in molecular switches and stimuli‐responsive supramolecular materials.
Twisted boron-based biradicals featuring unsaturated C\(_2\)R\(_2\) (R=Et, Me) bridges and stabilization by cyclic (alkyl)(amino)carbenes (CAACs) were recently prepared. These species show remarkable geometrical and electronic differences with respect to their unbridged counterparts. Herein, a thorough computational investigation on the origin of their distinct electrostructural properties is performed. It is shown that steric effects are mostly responsible for the preference for twisted over planar structures. The ground-state multiplicity of the twisted structure is modulated by the σ framework of the bridge, and different R groups lead to distinct multiplicities. In line with the experimental data, a planar structure driven by delocalization effects is observed as global minimum for R=H. The synthetic elusiveness of C\(_2\)R\(_2\)-bridged systems featuring N-heterocyclic carbenes (NHCs) was also investigated. These results could contribute to the engineering of novel main group biradicals.
In the experiments presented in this work, linear and non-linear femtosecond time-resolved spectrsocopy were applied to investigate the structure-function and functiondynamics relationship in biological and artificially designed systems. The experiments presented in this work utilize femtosecond time-resolved transient absorption and transient grating as well as picosecond time-resolved fluorescence spectroscopy to investigate the photophysics and photochemistry of biological photoreceptors and address the light-induced excited-state processes in a particular molecular device that serves as a - structurally - very simple light-harvesting antenna and potentially as a catalysis-switch for the production of hydrogen in solution. The combination of white-light probe transient absorption and coherent transient grating spectroscopies yields spectral information about the excited state absorption in concert with high quality, high signal-to-noise kinetic transients, which allow for precise fitting and therefore very accurate time-constants to be extracted from the data. The use of femtosecond time-resolved transient grating spectroscopy is relatively uncommon in addressing questions concerning the excited-state reaction pathways of complex (biological) systems, and therefore the experiments presented in this work constitute according to the literature the first studies applying this technique to a a metalloporphyrin and an artificial light-harvesting antenna.
The experimental technique predominantly employed within the scope of this Thesis constitutes one subarea of femtochemistry: the time-resolved spectroscopy of photoin-
duced chemical reactions in the liquid phase by means of molecular signatures in the mid-infrared (MIR) spectral range. Probing transient vibrational states, i.e., dynamic
changes in the vibrational motion of specic molecular subunits or functional Groups allows for a distinct separation and assignment of measured signals to emerging molecular species. For this purpose, one key building block is indispensable, which most of the investigations carried out within the eld of femtochemistry have in common: a coherent light source delivering ultrashort laser pulses with a temporal duration that matches the femtosecond time scale on which molecular motions typically occur. This instrumentation enables the observation of photoinduced chemical reactions from the
starting point|the excitation event to the appearance of intermediates to the nal formation of stable photoproducts after several pico- or nanoseconds.
This work comprises the acquisition and presentation of time-resolved spectroscopic data related to promising molecular systems upon photoexcitation as well as the im-
plementation and testing of experimental optical techniques both for the presented experiments but as well for experiments conceivable in the future. In addition, linear spectroscopy measurements and quantum-chemical simulations on the emerging chemical species have been carried out. In so doing, the primary processes and subse-
quently emerging reaction products of two compounds on a timescale of several nanoseconds after photoexcitation have been elucidated in great detail. Both compounds, the
[Mn(CO)3(tpm)]+ (tpm = tris(2-pyrazolyl)methane) CO-releasing molecule (CORM) and the 5-diazo Meldrum's acid (DMA), are of academic interest but in addition belong
to molecular classes that might be utilized in the near future as dark-stable prodrugs under physiological conditions or that are already utilized in industrial chemistry procedures, respectively. The ndings of both studies gave rise to implement and examine two techniques for prospective transient absorption experiments, namely the shaping and characterization of ultraviolet (UV) laser pulses and the recording of two-photon excitation spectra. Beyond that, since each of the depicted experiments is based on the detection of weak transient absorption signals in the MIR spectral region, two dif-
ferent detection schemes, via chirped-pulse upconversion (CPU) on the one hand and via direct multichannel MCT detection on the other hand, have been juxtaposed at the
conclusion of this work. Since both techniques are suitable in femtosecond pump-probe measurements but thereby exhibit individual strengths and weaknesses, a comparative study provides clarication of the respective pros and cons. The first study introduced within this work investigates the complex photochemistry
of DMA, a photoactive compound used in lithography and industrial chemistry. By femtosecond MIR transient absorption spectroscopy covering several nanoseconds, the
light-induced dynamics and ultrafast formation of several photoproducts from the manifold of reaction pathways have been disclosed to form a coherent picture of the overall
reaction scheme. After UV excitation of DMA dissolved in methanol to the second excited state S2, 70% of excited molecules relax back to the S0 ground state. In compet-
ing processes, they can either undergo an intramolecular Wolff rearrangement to form ketene, which reacts with a solvent molecule to an enol intermediate and further to carboxylate ester, or they rst relax to the DMA S1 state, from where they can isomerize to a diazirine. The third competing reaction channel, having the lowest quantum efficiency with respect to the rst two channels, is the formation of a singlet carbene out of the S1 state. From there an ylide can arise or, via an intersystem crossing, the triplet form of the carbene follows. Whereas the primary reaction steps occur on a picosecond timescale, the subsequently arising intermediates and stable photoproducts are formed
within a few hundreds to thousands of picoseconds. For a reliable identication of the involved compounds, density functional theory calculations on the normal modes and
Fourier-transform infrared spectroscopy of the reactant and the photoproducts in the chemical equilibrium accompany the analysis of the transient spectra. Additional experiments in ethanol and isopropanol led to slight spectral shifts as well as elongated time
constants due to steric hindrance in transient spectra connected with the ester Formation channel, further substantiating the assignment of the occurring reaction pathways and photoproducts.
The study demonstrated that the combination of linear and time-resolved spectroscopic measurements in conjunction with quantum-chemical calculations constitutes a powerful tool to unravel even highly complex photoreactions exhibiting multiple consecutive intermediate states within parallel reaction pathways. Although some of the individual reaction steps, for example the ketene formation via Wolff rearrangement, have been observed on ultrashort time scales before, this work encompassed the Observation of the whole set of appearing photoproducts of DMA in different alcohol solutions within several nanoseconds. In this sense, the ultrafast photochemistry of DMA represents a prototype example for a multisequential reaction scheme, elucidated by the capabilities of femtosecond MIR spectroscopy.
With a modified instrumentation concerning amongst others the system delivering the fundamental laser pulses or the generation of the UV pump pulses, the next ob-
jective within this work was to elucidate the primary processes upon UV Irradiation of a manganese tricarbonyl CORM in aqueous environment. The time-resolved
experiment was performed with two different pump wavelengths and furthermore supported by linear spectroscopy methods and time-dependent density functional theory (TDDFT) calculations on the excited states as well as DFT calculations on the ground
states. The measurements revealed that irradiating the compound with UV excitation pulses primarily leads to ultrafast photolysis of one CO ligand. Geminate recombination may occur within one picosecond but it remains a minor process as the photolyzed CO
group is liberated and the unoccupied coordination site is predominantly filled by an incoming solvent molecule. There was no evidence for hot CO bands, i.e., the remaining CO ligands|in the dicarbonyl photoproduct as well as in the intact CORM are not vibrationally excited through the UV excitation of the CORM. According to this, the excess energy merges into low-frequency vibrational modes associated with the molecule as a whole. Since studies on a macroscopic scale at irradiation times of several minutes prove that UV irradiation eventually leads to the release of two or even all three CO
ligands, further loss of CO most likely necessitates manganese oxidation or another interaction with light. To clarify the latter, a consecutive UV pulse was employed in order to excite the photoproducts subsequent to the initial pump interaction. However, the data obtained was not instructive enough to denitely exclude the manganese oxidation being responsible for the loss of further CO groups. Besides the exchange of a CO Group by a solvent molecule or the geminate recombination, the employment of two different excitation wavelengths in combination with ndings derived from the TDDFT calculations suggested another reaction process, namely the possibility that the excitation does not lead to any bond cleavage at all. As the CORM under investigation is tissue-selective and cytotoxic against cancer cells, knowledge of these rst photoinduced reaction steps is essential for a full understanding of its biological activity. Inspired by these two studies, experimental techniques for prospective transient absorption measurements have been implemented and tested within preparative measure-
ments. First, in the course of a UV-pump-MIR-probe experiment with specically tailored excitation pulses, one could pursue the aim of coherently controlling the outcome of a photoreaction in the liquid phase. Out of the rich photochemistry of DMA the vibrational signature of a particular molecular species might thereby serve as a feedback signal, which is a central part of a learning loop that adaptively determines the pulse shape that steers the quantum mechanical system upon photoexcitation into a desired direction. This motivated the installation and testing of devices by means of which the shaping and characterization of ultrashort laser pulses in the UV could be performed. Second, motivated by the biological applications of CORMs, one can imagine a scenario where a certain amount of CORMs is deposited inside cancerous tissue. Since the activation of CO loss by means of UV pulses is not possible due to the absorption characteristics of biological tissue, the simultaneous excitation via two photons from the visible spectral regime seems appealing. However, success or failure of such an application depends on whether the deposited compound efficiently absorbs two photons simultaneously, i.e., whether the two-photon absorption cross section is large enough. Therefore, a setup to record two-photon excitation spectra under full consideration of
the crucial laser pulse parameters like the pulse duration, energy and central wavelength was arranged and tested. The rst results were obtained with a commercially available reference system (Mn2CO10) but the setup as well as the described measurement and
data analysis procedure can easily be applied to record the two-photon absorption cross section of more promising molecular systems. Third, as the detection of probe pulses
in the MIR spectral region is part of each time-resolved measurement throughout this thesis, a comparison between the newly established technique of CPU and direct multi-
channel MCT detection is presented by means of pump{probe experiments on Mn2CO10 and Co4CO12 with a 1 kHz shot-to-shot data acquisition. It was shown that the CPU detection technique scores with its high spectral resolution and coverage of the easy-to-handle and more cost-effective CCD detectors. On the other hand, in the course of the additional nonlinear upconversion process intensity fluctuations of the chirped fundamental pulses are transferred to the probe spectrum in the visible regime. This entails a lower signal-to-noise ratio than the direct MCT detection, which can be compensated by an additional normalization procedure applied to the CPU probe pulses. As a consequence, the CPU detection scheme offers more flexibility for future investigations
employing MIR probe pulses. This is of great importance for many applications within the presented eld of femtochemistry as a huge variety of time-resolved investigations on a multitude of systems in the liquid phase is based on the detection of weak transient
absorption signals in the MIR spectral region.
Untersuchungen an biologischen Proben mit verschiedenen Raman- und SERS-spektroskopischen Techniken
(2003)
Diese Arbeit befasst sich mit der Entwicklung und Erprobung geeigneter Methoden zur Raman-spektroskopischen Untersuchung empfindlicher, insbesondere biologischer Proben. Das Ziel dabei ist, ein Werkzeug zur Verfügung zu stellen, mit dem es möglich ist, detaillierte Informationen über die Inhaltsstoffe einer Probe und deren räumlichen Verteilung zu sammeln. Diese Daten sind beispielsweise für die Qualitätssicherung pharmazeutischer Produktionen notwendig. Zu diesem Zweck wurden zwei verschiedene Ansätze verfolgt: ein Raman-Spektrometer wurde zum einen mit einer Glasfasersonde, zum anderen mit einer optischen Gradientenfalle kombiniert. Beide Ansätze wurden getestet und mit ihnen biologische Fragestellungen bearbeitet. Die Empfindlichkeit biologischer Proben und die geringe Konzentration ihrer Inhaltsstoffe macht es dabei notwendig, besonderen Wert auf probenschonende Messverfahren und eine hohe Nachweisempfindlichkeit zu legen. Die Raman- bzw. SERS-Spektroskopie ist hierzu in der Lage und erfordert gleichzeitig nur eine minimale Probenpräparation. Anhand der präsentierten Experimente konnte gezeigt werden, dass sich die SERS-Glasfasersonde besonders zur Untersuchung empfindlicher Proben eignet. Insbesondere erlaubt sie minimal-invasives Arbeiten an biologischen Materialien. Es konnte außerdem gezeigt werden, dass die Sonde aufgrund ihrer geometrischen Beschaffenheit eine gute Ortsauflösung, bis in den Sub-Mikrometerbereich, bei den Messungen erlaubt. Daher eignet sich die Fasersonde besonders zur Untersuchung von hochempfindlichen biologischen Proben bei gleichzeitig sehr geringem Probenbedarf. Mit der optischen Gradientenfalle, als zweite Methode, hat man ein Werkzeug zur Hand, mit dem es möglich ist, einzelne Mikroorganismen oder Mikropartikel in Suspension zu vermessen. Bei Arbeit mit der optischen Gradientenfalle ist eine freie, dreidimensionale Manipulation der gefangenen Zellen im Probengefäß möglich. Auf diese Weise können einzelne Zellen über längere Zeit stabil im Laserfokus gehalten werden, wodurch längere Integrationszeiten möglich werden. Außerdem kann man auf diese Weise eine Immobilisierung der suspendierten Zellen auf einer funktionalisierten Oberfläche vermeiden, wodurch unerwünschte Effekte auf das zu messende Spektrum, wie z. B. Verschiebungen einzelner Banden oder Änderungen in den relativen Bandenintensitäten, ausgeschlossen werden können. Zur Untersuchung partikulärer Verunreinigungen ist es nicht notwendig, die Lösung aus dem Gefäß heraus zu präparieren. Vielmehr können die Mikropartikel durch die optische Gradientenfalle in der Lösung festgehalten und spektroskopisch identifiziert werden. Dies ermöglicht beispielsweise die Charakterisierung von Verunreinigungen in pharmazeutischen Lösungen, ohne dass dafür Ampullen geöffnet werden müssten. Auf diese Weise können Kontaminantien identifiziert werden, ohne Gefahr zu laufen, bei der Probenpräparation weitere Verunreinigungen zu verursachen und damit die Messungen zu verfälschen. Durch die Kombination eines Raman-mikroskopischen Aufbaus mit der SERS-Glasfasersonde bzw. der optischen Gradientenfalle ist es gelungen, Fragestellungen an biologischen Systemen in sehr Proben-schonender, aber gleichzeitig hoch-ortsauflösender Weise zu bearbeiten. Durch die Verwendung nicht-kontaminierender SERS-Sonden ist es möglich, zusätzliche Verstärkungseffekte zu erzielen. Die verwendeten Anregungslaserleistungen können daher generell niedrig gehalten werden. Dennoch erhält man aussagekräftige Spektren in einer akzeptablen Zeit. Die Zwei-Laser-Lösung für die optische Gradientenfalle stellt ein zuverlässiges Werkzeug zur berührungsfreien Manipulation kleiner Partikel bei gleichzeitiger Flexibilität in Bezug auf die Anregungswellenlänge dar.
In dieser Arbeit werden Pigmente in verschiedenen archäologischen Materialien mittels Mikro-Raman-Spektroskopie archäometrisch untersucht. Zusätzlich werden Analysen mittels Elektronenstrahl-Mikrosonde und Röntgenpulverdiffraktometrie durchgeführt, um einerseits die Ergebnisse der spektroskopischen Untersuchungen zu stützen und andererseits die Vor- und Nachteile der Mikro-Raman-Spektrokopie gegenüber diesen Methoden aufzuzeigen. Im ersten Teil werden Pigmentanalysen römischer Fresken in den Provinzen Noricum, Raetien und Obergermanien vorgestellt, um daraus Informationen über Umfang und Variationsbreite der Farbpalette antiker Maler abzuleiten sowie Rückschlüsse auf die Herkunft der Rohstoffe und eventuelle Handelsrouten zu ziehen. Die Möglichkeit der zeitlichen Einordnung von Fresken anhand der verwendeten Pigmente wird ebenfalls diskutiert. Im zweiten Teil wird die chemische Zusammensetzung antiker Gläser am Beispiel einer Sammlung von Mosaikgläsern aus dem Martin-von-Wagner-Museum Würzburg und verschiedener bunter Glasperlen aus Sri Lanka und Oman untersucht, um Informationen über die verwendeten Rohmaterialien und die Technologie der antiken Glasproduktion zu gewinnen. Insbesondere wird auf die Pigmente eingegangen, die die Farbigkeit der Gläser verursachen. Anhand der Differenzen in den Glasrezepturen und Pigmenten der Gläser wird eine zeitliche Einordnung erörtert.
Using Photoionization to Investigate Reactive Boron Species and the Kinetics of Hydrocarbon Radicals
(2021)
This thesis highlights the importance of isomer-selective approaches for the complete analysis of chemical processes. The method of choice is photoelectron/photoion coincidence spectroscopy, which allows simultaneous detection of electrons and ions coming from a single ionization event. Ionization techniques are sensitive and can record multiple species simultaneously, rendering them ideal tools to probe molecular transformations. Coupling these setups to synchrotron radiation allows one to analyze complex mixtures with isomer selectivity, based on ionization energies and vibrational structure in the cation, without any prior separation steps. Only few setups exist that can be used to gather these data, although their impact and applicability is growing steadily in various fields. For closed-shell species an easier and more widely used method is gas-chromatography, but most open shell species would not survive the separation process. Due to the reactivity of radicals they have to be created by selectively converting stable precursor molecules. Depending on the radical generation method different properties can be investigated ranging from thermodynamic data, over concentrations in high temperature environments, to chemical kinetics.
The first part of this thesis deals with the determination of bimolecular rate constants. Isomeric hydrocarbon radicals were generated by a high intense UV light pulses and their kinetics with oxygen was measured. The pressure dependence of different isomers in the falloff region was compared to theoretical models, and their reactivity could be explained.
The second part deals with boron containing compounds in various electronic situations. The corresponding precursors were successfully synthesized or could be bought. They were subjected to fluorine atoms in chemical reactors or destroyed pyrolytically at high temperatures. Most investigated species exhibited vibronic effects that could be elucidated using high level computations.
A series of combustion relevant species like radicals, carbenes and polycyclic aromatic hydrocarbons were characterized in the gas phase by vacuum UV synchrotron radiation and their ionization energies (IE) and further spectroscopic details of the respective cations were retrieved from threshold photoelectron spectra. The reactive intermediates were generated by flash vacuum pyrolysis from stable precursor molecules. Furthermore three polycyclic aromatic hydrocarbons were investigated by threshold photoelectron spectroscopy, too. The experiment was performed at the VUV beamline of the Swiss Light Source in Villigen/Switzerland and the iPEPICO (imaging photoelectron photoion coincidence) setup was applied to correlate ions and electrons from the same ionization event. From the threshold photoelectron spectra and from quantum chemical computations the vibrational structure of the molecule cations and the geometry changes upon ionization were assigned. The ionization energies of the two C4H5 isomers 2-butyn-1-yl and 1-butyn-3-yl were assigned to 7.94±0.02 eV and 7.97±0.02 eV, respectively. The isomerization between the two isomers was computed to have a barrier of 2.20 eV, so a rearrangement between the two radicals cannot be excluded. From the threshold photoelectron spectra of the two constitutional C4H7 isomers 1-methylallyl and 2-methylallyl the ionization energies were assigned to 7.48±0.02 eV and to 7.59±0.02 eV for 1-E-methylallyl and 1-Z-methylallyl, as well as to 7.88±0.01 eV for 2-methylallyl. The two radicals 9-fluorenyl, C13H9, and benzhydryl, C13H11, were observed to ionize at 7.01±0.02 eV and 6.7 eV. The threshold photoelectron spectrum of benzhydryl also incorporated the signal of the diphenylmethyl carbene, C13H10, which has an IE at 6.8 eV. In addition, the head-to-head dimers of 9-fluorenyl and benzhydryl were observed as products in the pyrolysis. C26H18 has an IE at 7.69±0.04 eV and C26H22 has an IE at 8.13±0.04 eV. The three polycyclic aromatic hydrocarbon DHP (C14H16) 1-PEN (C18H22) and THCT (C22H16) were investigated in an effusive beam. The ionization energies were determined to IE(DHP)= 7.38±0.02 eV, IE(1-PEN)=7.58±0.05 eV and IE(THCT)=6.40±0.02 eV. Furthermore the thermal decomposition and the dissociative photoionization of diazomeldrum’s acid was investigated. The pyrolysis products yielded beside several other products the two not yet (by photoelectron spectroscopy) characterized molecules E-formylketene, C3O2H2 and 2-diazoethenone, N2C2O. The dissociative photoionization showed the Wolff rearrangement to occur at higher internal energies.
In this work, the laser control of molecules was investigated theoretically. In doing so, emphasis was layed on entering vectorial properties and in particular the orientation in the laboratory frame. Therefore, the rotational degree of freedom had to be included in the quantum mechanical description. The coupled vibrational and rotational dynamics was examined, which is usually not done in coherent control theory. Local control theory was applied, where the field is determined from the dynamics of a system, which reacts with an instantaneous response to the perturbation and, in turn, determines the field again. Thus, the field is entangled with the quantum mechanical motion and the presented examples document, that this leads to an intuitive interpretation of the fields in terms of the underlying molecular dynamics. The limiting case of a classical treatment was shown to give similar results and hence, eases to understand the complicated structure of the control fields. In a different approach, the phase- and amplitude shaping of laser fields was systematically studied in the context of controlling population transfer in molecules.
Das erste Ziel der vorliegenden Dissertation bestand darin, ein bereits bestehendes TOF-MS-Setup dahingehend zu erweitern, um damit Velocity Map Imaging-Experimente durchführen zu können. Dies erforderte zunächst die Konzipierung und Programmierung einiger für die Datenaufnahme, -verarbeitung und -analyse benötigter LabView-Anwendungen. Anschließend konnten erste Kalibrierexperimente an Methyliodid, in denen wichtige experimentelle Parameter identifiziert und optimiert wurden, durchgeführt werden. Außerdem gelang es dadurch, die Messgenauigkeit des Setups auf 0.7 % und dessen Auflösungsvermögen auf 4.4 % zu bestimmen, was im Bereich für VMI-Apparaturen typischer Werte liegt. Zur weiteren Überprüfung der Funktionstüchtigkeit des Setups wurde in ersten zeitaufgelösten Experimenten im Folgenden die Desaktivierung des S1-Zustands von Pyridin untersucht. Neben der Reproduktion einiger bereits literaturbekannter Resultate konnten dabei zusätzlich die im Multiphotonen-Ionisationsschritt populierten Rydberg-Zustände identifiziert werden. Anschließend wurde mit Experimenten an bisher weniger gut untersuchten organischen Aromaten und Heteroaromaten fortgefahren. Das Ziel dieser Studien lag in der Aufklärung der photoinduzierten Dynamiken der Verbindungen, wobei das zur Verfügung stehende ps-Lasersystem die Möglichkeit bot, die Desaktivierung elektronisch angeregter Zustände gezielt in Abhängigkeit von deren Schwingungsenergie zu untersuchen. Der darin bestehende Vorteil zeigte sich vor allem in Studien an Tolan und Phenanthridin, deren erste angeregte, optisch aktive Zustände am Origin Lebensdauern im ns-Bereich aufweisen, die sich mit zunehmender vibronischer Anregung jedoch auf bis zu 10 ps verringern. Als Grund dafür konnten nichtstrahlende Desaktivierungsprozesse, für deren Eintreten eine energetische Barriere überwunden werden muss, identifiziert werden. Während in Tolan nach Photoanregung ein Übergang in einen (πσ∗)-Zustand, der zur Ausbildung einer trans-bent-Struktur führt, erfolgt, ist im Falle von Phenanthridin vermutlich ein El-Sayed-erlaubter ISC-Übergang in einen 3(nπ∗)-Zustand für die drastische Verkürzung der S1-Lebensdauer verantwortlich. Ein solcher konnte weder im zu Phenanthridin isomerischen Benzo[h]quinolin, noch in dessen PAH-Muttermolekül Phenanthren beobachtet werden, was auf die höhere energetische Lage bzw. die Abwesenheit des mittels ISC populierten 3(nπ∗)-Zustands in diesen Molekülen zurückgeführt werden kann. In weiteren im Rahmen der vorliegenden Arbeit durchgeführten Experimente wurden zudem die aromatischen Moleküle Acenaphthylen und 4-(Dimethylamino)benzethin (DMABE) untersucht. Zeitaufgelöste Studien zeigten dabei, dass die Desaktivierung der S2-Zustände beider Moleküle auf der sub-ps-Zeitskala stattfindet und mit dem vorhandenen Lasersystem daher nicht aufgelöst werden kann. In Acenaphthylen erfolgt die S2-Relaxation größtenteils über einen sequentiellen IC-Mechanismus, innerhalb dem der S1-Zustand des Moleküls intermediär besetzt wird. Dessen Lebensdauer konnte am Origin auf 380 ps bestimmt werden, fällt mit steigender Schwingungsanregung jedoch auf bis zu 55 ps ab. Für die Desaktivierung des S2-Zustands von DMABE konnte hingegen ein paralleles Relaxationsmodell, in dem neben dem S1-Zustand ein weiterer elektronisch angeregter Zustand populiert wird, nachgewiesen werden. Bei diesem könnte es sich möglicherweise um einen (πσ∗)-Zustand, dessen Besetzung die Ausbildung einer trans-bent-Geometrie innerhalb der Acetylen-Einheit des Moleküls zur Folge hat, handeln. Einen weiteren großen Teil der vorliegenden Dissertation nahmen Experimente an van-der-Waals-gebundenen Clustersystemen ein. Im Fokus der Studien standen dabei Moleküle mit ausgedehnten aromatischen π-Systemen, da solche eine hohe Relevanz für verschiedene materialwissenschaftliche Forschungsgebiete besitzen. Ein Beispiel hierfür ist Tetracen, welches als Modellsystem für die Untersuchung von Singlet Fission-Prozessen angesehen wird. In Kombination mit nichtadiabatischen Surface-Hopping-Simulationen zeigten Experimente an Tetracen-Dimeren, dass nach deren S2-Anregung zunächst ein schneller S1←S2-Übergang (τ < 1 ps), gefolgt von der Ausbildung einer Excimerstruktur, stattfindet. Letztere erfolgt mit einer Zeitkonstante von 62 ps und führt zu einem Anstieg des transienten Ionensignals, wohingegen die Desaktivierung des Excimer-Zustands von einem abklingenden Signalbeitrag mit τ = 123 ps repräsentiert wird. Wenngleich über die weitere Relaxation der Excimerspezies zum gegenwärtigen Zeitpunkt keine Aussage getroffen werden kann, besteht damit die Möglichkeit, dass Excimer-Zustände als Zwischenstufe im SF-Mechanismus isolierter Tetracen-Dimere auftreten. In zeitaufgelösten Experimenten an Phenanthren-Dimeren konnte ebenfalls ein Anstieg des transienten Signals mit einer vergleichbaren Zeitkonstante von τ = 86 ps, der jedoch auf einem konstanten Signaloffset endet, gefunden werden. Dies deutet darauf hin, dass auch Phenanthren-Dimere in der Lage sind, Excimerstrukturen, die im Gegensatz zu denen des Tetracens jedoch deutlich langlebiger sind, auszubilden. Studien an den Dimerspezies der Azaphenanthrene Benzo[h]quinolin und Phenanthridin offenbarten hingegen etwas schnellere Relaxationen mit Zeitkonstanten von 15 bzw. 40 ps. Zudem zeigten beide Spezies eine stark ausgeprägte Fragmentation, sodass für deren Untersuchung auf die VMI-Detektionsmethode zurückgegriffen werden musste. Dadurch wurde deutlich, dass sich Photoionen-Imaging-Experimente hervorragend für Studien an schwach gebundenen Clustersystemen eignen, da diese die Separation verschiedener Signalbeiträge innerhalb eines betrachteten Massenkanals ermöglichen.