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In conclusion, the present thesis demonstrates that the highly desired J-type aggregation of functional perylene bisimide chromophores can be achieved by proper design of monomeric building blocks that direct self-assemble by mutual effects of hydrogen bonding and pi-pi interaction, and on the other hand, are prevented to assemble in columnar stacks owing to their twisted pi-conjugated core and sterically demanding substituents. Furthermore, the self-assembly studies gave new insights into the dynamic aggregation process of low-dimensional extended assemblies with strongly excitonically coupled chromophores. The relationship between commonly known cyanine dye aggregates like that of THIATS and that of the present PBI 1a was investigated by absorption and fluorescence spectroscopy at low temperatures down to 5 K. The formerly unprecedented functional properties of PBI aggregates that are expressed in J-type excitonic coupling hold promise for application in optoelectronic and photovoltaic devices.
The research presented in this thesis illustrates that self-assembly of organic molecules guided by intermolecular forces is a versatile bottom-up approach towards functional materials. Through the specific design of the monomers, supramolecular architectures with distinct spatial arrangement of the individual building blocks can be realized. Particularly intriguing materials can be achieved when applying the supramolecular approach to molecules forming liquid-crystalline phases as these arrange in ordered, yet mobile structures. Therefore, they exhibit anisotropic properties on a macroscopic level. It is pivotal to precisely control the interchromophoric arrangement as functions originate in the complex structures that are formed upon self-assembly. Consequently, the aim of this thesis was the synthesis and characterization of liquid-crystalline phases with defined supramolecular arrangements as well as the investigation of the structure-property relationship. For this purpose, perylene bisimide and diketopyrrolopyrrole chromophores were used as they constitute ideal building blocks towards functional supramolecular materials due to their thermal stability, lightfastness, as well as excellent optical and electronic features desirable for the application in, e.g., organic electronics.
This thesis deals with the synthesis of improved organic semiconductors, the detailed investigation of the molecular properties and the solid state arrangements revealed by single crystal X-ray diffraction and finally the development of structureperformance dependencies by measuring of the charge carrier mobilities of the derivatives in thin film transistors. The two main-goals of this thesis were achieved. Well soluble acene derivatives for spin-coated TFTs were obtained, showing charge carrier mobilities in the range of polymer p-type materials. Novel core-fluorinated perylene bisimide dyes were synthesized particularly and the use of electron deficient substituents lead to PBIs with outstanding air-stable mobilities in thin film transistors prepared by vacuum deposition techniques. The relationship between performance, air stability and solid state packing was elucidated in detail by single crystal X-ray diffraction analysis.
The covalent linkage of the aryloxy-substituents through macrocyclisation was applied for the synthesis of perylene bisimide atropo-enantiomers. The synthesis of macrocyclic perylene bisimides was achieved by using a tetra(3-hydroxyphenoxy)-functionalized perylene bisimide with achiral 2,6-diisopropylphenyl as imide substituent through Williamson´s etherfication which could be realized for four different oligoethylene glycol bridging units. Two regioisomeric macrocycles, namely the diagonally bridged (1,7- and 6,12- linkage) and the laterally bridged (1,12- and 6,7-linkage) isomers, were obtained for each bridging unit. The structural assignment of the isolated regioisomeric macrocycles was unambiguously accomplished by X-ray analysis of two macrocycles and by 1H NMR spectroscopy for all isomers. The conformational influence of the aryloxy-substituents on the functional properties of this class of chromophores could be derived by comparison of the optical and electrochemical properties of all isolated macrocylces with those of an open-chained reference compound. It was shown that the aryloxy-substituents prefer a lateral conformation in solution. Furthermore, solvent dependent fluorescence studies indicated that a photoinduced electron transfer process is of importance for the fluorescence quenching of electron-rich aryloxy-substituted perylene bisimides. The resolution of the atropo-diastereomers of diagonally bridged macrocyclic perylene bisimides with chiral 2-(R)-octylamine as imide substituent and diethylene glycol bridging units could be accomplished by semi-preparative HPLC on a chiral column. The chiroptical properties of the isolated epimerically pure macrocycles were determined by CD spectroscopy. Based on the experimental CD spectra, the stereochemical assignment of the isolated epimers was accomplished by application of the excition chirality method and confirmed by quantum chemical calculation of the CD spectra. The synthetical concept was extended successfully to 1,7-diaryloxy-substituted perylene bisimides. The structure of the diagonally bridged macrocycle was unambiguously confirmed by X-ray analysis and NMR spectroscopy. The atropo-enantiomers of this macrocycle could be resolved by semi-preparative HPLC on a chiral column and the assignment of the absolute configuration was achieved by comparison of the CD spectra of the resolved enantiomers with those of epimerically pure bis(macrocycles) reported before. By comparison of the X-ray structures obtained for the racemic mixture as well as one enantiomer important information could be extracted for the formation of p-dimers of perylene bisimides. The dependence of the interconversion barrier on the bulkiness of the bay-substituents was investigated for four halogen-substituted perylene bisimides. The dynamic properties were investigated by temperature-dependent NMR spectroscopy and kinectic measurements using CD spectroscopy. By applying the concept of the “apparent overlap” a convincing linear relationship between the size of the substituents and the free enthalpy of activation could be derived. Furthermore, the resolution of the atropo-diastereomers or enantiomers of the tetrachloro and tetrabromo-substituted derivates was accomplished, whereupon especially the 1,6,7,12-tetrabromosubstituted perylene bisimide provided at room temperature stable enantiomers. Additionally, the derived structure-property relationship allows the design of conformationally stable perylene bisimide enantiomers by proper choice of the bay substituents. In order to utilize the reversibility of self-assembly for the quantitative formation of macrocyclic perylene bisimides, a tetrazinc porphyrin-functionalized perylene bisimide was synthesized. The self-assembly of the zinc porphyrin perylene bisimide bichromophoric building block and diazabicyclo-[2.2.2]-undecane into the desired 1:2 sandwich complex was investigated by UV/Vis and 1H NMR spectroscopy and the macrocyclic structure was unequivocally proven by diffusion-ordered NMR spectroscopy (DOSY NMR). Furthermore, the controlled deposition of these well-defined macrocycles on highly ordered pyrolitic graphite (HOPG) was demonstrated by atomic force microscopy (AFM) investigations. The alignment of a linear amino functionalised p-conjugated polymers upon addition of the bichromphoric tetrazinc porphyrin-perylene bisimide was investigated by UV/Vis spectroscopy and AFM measurement. The surface analysis by AFM investigations revealed that the bichromophoric system composed of perylene bisimide and zinc porphyrin is able to cross-link the linear p-conjugated polymer over a wide range of the graphite surface which provided a defined arrangement of three different functional p-systems.
In this thesis the syntheses and detailed investigations on two foldable PBI systems were presented. The reversible, solvent-dependet folding/unfolding-behavior was used to study the ground and excited states properties of folda-dimer and folda-trimer by means of different spectroscopic methods as well as theoretical studies. The switching between charge transfer or excimer formation pathways of photoexcited molecules influenced by the spatial arrangement of chromophores within defined dye systems illustrates the impact of conformational preferences on functional properties.
The thesis enhances the strategy of non-destructive fluorescence read-out in rylene bisimide-diarylethene containing photochromic systems. The fluorescence of the emitter unit is quenched by a photoinduced electron transfer only to one of the isomeric forms of the photochrome. The driving force of the fuorescence-quenching electron transfer was calculated by the help of the Rehm-Weller equation. The novel photochromic systems satisfy the necessary requirements for non-destructive read-out in write/read/erase fluorescent memory devices.
The subject of this thesis is the synthesis and characterization of PBI-based fluorescent metallosupramolecular polymers and cyclic arrays. Terpyridine receptor functionalized PBIs of predesigned geometry have been used as building blocks to construct desired macromolecular structures through metal-ion-directed self-assembly. These metallosupramolecular architectures have been investigated by NMR, UV/Vis and fluorescence spectroscopy, mass spectrometry, and atomic force microscopy.
The main objective of this thesis was the design and synthesis of perylene bisimide dyes with sufficient water-solubility for the construction of self-assembled architectures in aqueous solutions. Beside these tasks another goal of this project was the control over the self-assembly process in terms of aggregate size and helicity, respectively. Within this thesis an appropriate synthesis for spermine-functionalized perylene bisimide dyes was developed and conducted successfully. The characterization of these building blocks and their course of self-assembly were investigated by NMR, UV/Vis and fluorescence spectroscopy as well as by atomic force and transmission electron microscopy. For the better understanding of the experimental results theoretical calculations were performed.
Complexation properties of 2,2':6',2''-terpyridine (tpy) have been studied with a series of first row transition metal ions by UV-vis, 1H NMR and isothermal titration calorimetry and ƒ´H values for the tpy complexation processes have been determined. These studies reveal that Zn2+ is the best suited metal ion for the reversible coordination of the terpyridine ligand. Thus, supramolecular coordination polymerization of perylene bisimide fluorophores containing terpyridine functionalities have been investigated by using Zn2+ as metal ion. The formation of the dimeric complexes in the case of monotopic model comounds and coordination polymerization of ditopic functional building blocks have been confirmed by 1H NMR studies. The optical properties of dimeric and polymeric complexes have been investigated by UV-vis and fluorescence spectroscopy. The Zn2+ coordination to the terpyridine unit does not effect the advantageous fluorescence properties of perylene bisimide moieties. The reversibility of the formation of coordination polymers has been established by 1H NMR and additionally by DOSY NMR and fluorescence anisotropy measurements. Coordination polymer strands can be visualized by atomic force microscopy (AFM), which also reveals the formation of an ordered monolayer film at higher concentration. The average polymer length has been determined by AFM to 15 repeat units, which correlates well with the value estimated by 1H NMR to >10 repeat units.
This work is concerned with the syntheses and photophysical properties of para-xylylene bridged macrocycles nPBI with ring sizes from two to nine PBI units, as well as the complexation of polycyclic aromatic guest compounds.
With a reduced but substantial fluorescence quantum yield of 21% (in CHCl3) the free host 2PBI(4-tBu)4 can be used as a dual fluorescence probe. Upon encapsulation of rather electron-poor guests the fluorescence quenching interactions between the chromophores are prevented, leading to a significant fluorescence enhancement to > 90% (“turn-on”). On the other hand, the addition of electron-rich guest molecules induces an electron transfer from the guest to the electron-poor PBI chromophores and thus quenches the fluorescence entirely (“turn-off”). The photophysical properties of the host-guest complexes were studied by transient absorption spectroscopy. These measurements revealed that the charge transfer between guest and 2PBI(4-tBu)4 occurs in the “normal region” of the Marcus-parabola with the fastest charge separation rate for perylene. In contrast, the charge recombination back to the PBI ground state lies far in the “inverted region” of the Marcus-parabola.
Beside complexation of planar aromatic hydrocarbons into the cavity of the cyclophanes an encapsulation of fullerene into the cyclic trimer 3PBI(4-tBu)4 was observed. 3PBI(4-tBu)4 provides a tube-like structure in which the PBI subunits represent the walls of those tubes. The cavity has the optimal size for hosting fullerenes, with C70 fitting better than C60 and a binding constant that is higher by a factor of 10. TA spectroscopy in toluene that was performed on the C60@3PBI(4-tBu)4 complex revealed two energy transfer processes. The first one comes from the excited PBI to the fullerene, which subsequently populates the triplet state. From the fullerene triplet state a second energy transfer occurs back to the PBI to generate the PBI triplet state.
In all cycles that were studied by TA spectroscopy, symmetry-breaking charge separation (SB-CS) was observed in dichloromethane. This process is fastest within the PBI cyclophane 2PBI(4-tBu)4 and slows down for larger cycles, suggesting that the charge separation takes place through space and not through bonds. The charges then recombine to the PBI triplet state via a radical pair intersystem crossing (RP-ISC) mechanism, which could be used to generate singlet oxygen in yields of ~20%.
By changing the solvent to toluene an intramolecular folding of the even-numbered larger cycles was observed that quenches the fluorescence and increases the 0-1 transition band in the absorption spectra. Force field calculations of 4PBI(4-tBu)4 suggested a folding into pairs of dimers, which explains the remarkable odd-even effect with respect to the number of connected PBI chromophores and the resulting alternation in the absorption and fluorescence properties. Thus, the even-numbered macrocycles can fold in a way that all chromophores are in a paired arrangement, while the odd-numbered cycles have open conformations (3PBI(4-tBu)4, 5PBI(4-tBu)4, 7PBI(4-tBu)4) or at least additional unpaired PBI unit (9PBI(4-tBu)4).
With these experiments we could for the first time give insights in the interactions between cyclic PBI hosts and aromatic guest molecules. Associated with the encapsulation of guest molecules a variety of possible applications can be envisioned, like fluorescence sensing, chiral recognition and photodynamic therapy by singlet oxygen generation. Particularly, these macrocycles provide photophysical relaxation pathways of PBIs, like charge separation and recombination and triplet state formation that are hardly feasible in monomeric PBI dyes. Furthermore, diverse compound specific features were found, like the odd-even effect in the folding process or the transition of superficial nanostructures of the tetrameric cycle influenced by the AFM tip. The comprehensive properties of these macrocycles provide the basis for further oncoming studies and can serve as an inspiration for the synthesis of new macrocyclic compounds.