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The effective binding of anions like carboxylates and phosphates in aqueous solutions is of particular interest for various reasons. The natural archetypes of effective anion receptors are enzymes that contain often arginine as relevant amino acid in the binding pocket. For this reason, one class of artificial anion receptors that emerged more than two decades ago mimics the anion binding with the guanidinium group present in the amino acid side chain. In 1999, Schmuck and coworkers developed a new class of guanidinium-based oxo anion receptor that binds carboxylates even in aqueous media. The binding modes of the 2-(guanidiniocarbonyl)-1H-pyrroles are based on individually weak non-covalent interaction between artificial host and substrate like ion pairing and multiple hydrogen bonds. The zwitterionic derivative with substitution of a carboxylate group in position 5 of the pyrrole ring system shows a strong self-assembly to discrete dimers (dimer 1) with an estimated association constant of 170 M-1 even in water. In order to further improve the structure motif for an effective oxo anion binding it is therefore of great interest to quantify the different intermolecular interactions between two monomeric units of 1. Against this background several theoretical ab initio studies were conducted in order to elucidate the influences of intrinsic properties as well as solvent effects on the stability of self-assembled dimers. In chapter 4.1 the molecular interactions in dimer 1 were investigated by comparison to various “knock-out” analogues. In these analogues single hydrogen bonds were switched off by substitution of hydrogen donor atoms with either methylene groups or ether bridges. The calculations were done for vacuum and solvation, as represented by a conductor-like polarizable continuum. It could be shown that the application of a simple continuum solvent model fails to predict the absolute energies of the knock-out analogues in strongly polar solvents. However, the calculated trends can explain the relative stabilities. In chapter 4.2 the structural similarity of arginine with structure 1 was used in order to examine the dependence of self-assembly from the flexibility of the molecular structure. In chapter 4.2.1 new global minimum structures of the canonical and zwitterionic arginine in gas phase were found by means of exhaustive force field based conformational searches in conjunction with ab initio structure optimizations of the lowest energy conformers. Most of the newly identified minimum conformers of both the zwitterionic and canonical tautomer revealed geometrical arrangements with hitherto unreported stacked orientations of the terminal groups. Finally a novel global minimum structure was detected that is more than 8 kJ mol-1 lower in energy than the previously published conformers. The same strategy for finding minimum energy conformers of the arginine monomer has also been employed for the arginine dimer structures. While previous theoretical studies favoured directed hydrogen bonds the new global minimum structure MMFF1 is about 60 kJ mol-1 more stable and exhibits a stacked orientation of the guanidinium and carboxylate groups. The importance of rigidity on the dimer stability was proven by calculations of an artificially stiffened arginine dimer system. The high binding affinity dimer 1 results by about 50% from the rigidity of the monomers which prevents any intramolecular stabilization. In chapter 4.3 novel structure motifs with varying ring systems have been examined on a DFT level of theory in order to make proposals for an improved carboxylate binding motif. The direct dependency of the dimerization energy on an increasing dipole moment was demonstrated by various anellated ring structures. The influence of the delocalization in the monomer on the dimerization energy was examined by variation of the electronic structure of electronically decoupled biphenylenes. With the aid of various substituted 7-guanidinioindole-2-carboxylate derivatives we could show that the carbonyl function is mainly responsible for the advantageous preorganisation, whereas the effect on the acidity seems to be only of minor importance. In the last chapter cooperativity effects in supramolecular assemblies have been investigated. This was achieved by NMR shift calculations of adenosine-carboxylic acid complexes as model systems and comparison to experimental low-temperature NMR studies. We could demonstrate that only by applying vibrational averaged NMR shifts the experimental proton shifts obtained at very low temperatures in the hydrogen bond exchange regime could be reproduced.
Artificial light-harvesting (LH) systems have been obtained by self-assembly of naphthalene diimide-functionalized zinc chlorin dyads and triad in nonpolar, aprotic solvents. UV-vis, CD, and steady-state emission spectroscopy as well as atomic force microscopy showed that rod-like structures are formed by excitonic interactions of zinc chlorin units, while the appended naphthalene diimide dyes do not aggregate at the periphery of the cylinders. In all cases, photoexcitation of the enveloping naphthalene diimides at 540 and 620 nm, respectively, was followed by highly efficient energy-transfer processes to the inner zinc chlorin backbone, as revealed by time-resolved fluorescence spectroscopy on the picosecond time-scale. As a consequence, the LH efficiencies of zinc chlorin rod aggregates were increased by up to 63%. The effective utilization of solar energy recommends these biomimetic systems for an application in electronic materials on the nanoscale.
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 the first part of this work a new approach to measure transient absorption spectra of fluorescent compounds by means of laser flash photolysis technique was presented. Generally, the recorded transient absorption signal consists of transient absorption, fluorescence and ground state bleaching. Thus, for fluorescent chromophores a fluorescence correction is indispensable in order to obtain undisturbed absorption decay curves as well as accurate transient absorption spectra. Due to time response characteristics of the PMT detector the fluorescence contribution cannot be corrected by recording the fluorescence separately. Measuring two transient absorption signals with probe light differing in intensity, compounds with quantum yields up to ~ 35 % can be investigated. This is a major improvement because transient absorption spectroscopy is a powerful method to gain insight into the kinetics and the energy of excited states and information in the time domain of fluorescence are no longer lost. In the second part the synthesis and the photophysical characterisation of redox cascades were reported. These cascades consist of an acridine acceptor and up to three triarylamine donor subunits. The redox potentials of the triarylamines were tuned by adequate substituents in the para-position of the phenyl ring to ensure a directed redox gradient. Upon photoexcitation a locally excited state or a CT state is populated which then injects a hole onto the adjacent donor and consequently results in a CS state. Fluorescence and transient absorption measurements revealed that HT depends strongly on donor strength and solvent polarity. Formation of a CS state was only observed in case of strong terminal donors or polar solvents. A low lying localised triplet state acts as an energy trap and quenches all CS states even in case of the cascade with the strongest terminal donor in very polar solvents. Furthermore, population of a CS state catalyses the formation of this triplet states which results in a shorter lifetime of the CS state compared to the lifetime of the CT state of the corresponding reference compound. Compared to redox cascades already reported in literature, the electronic coupling between the redox centres was decreased by sterical as well as electronic effects. To prolong the lifetime of the CS state saturated spacers on the one hand and a perpendicular orientation of the acceptor and the adjacent donor on the other hand were selected. The twisting of the subunits forming the CT state results in a higher degree of charge separation but its contribution to increase the lifetimes of the CS states is of minor importance. The longer lifetime of the CS states can be ascribed to the saturated spacers. Experimental data in combination with calculated values indicate that charge recombination takes place in the Marcus normal region by a superexchange mechanisms. Although charge recombination of the known cascades is located in the Marcus inverted region, these CS states decay faster than the CS states of the compounds investigated in this work.
The present work deals with the synthesis and the investigation of the photophysical properties of covalently constructed calix[4]arene–perylene bisimide dye arrays containing various PBI units. The obtained conjugates are characterized with respect towards their application in a new, zigzag-type architecture of artificial light-harvesting systems. For this purpose, orange (core-unsubstituted), red (6,7,11,12-tert-butylphenoxy-functionalized) and green (1,7-pyrrolidino-substituted) perylene bisimide building blocks have been attached to the calix[4]arene scaffold. First, the monochromophoric reference systems have been studied, and second, the photophysical properties of a comprehensive series of newly synthesized, multichromophoric calix[4]arene–perylene bisimide conjugates showing efficient energy transfer processes between the individual dye subunits have been investigated. Furthermore, a series of bichromophoric compounds containing identical chromophoric units has been obtained. Towards this goal, a variety of spectroscopic techniques such as UV/vis absorption, steady state and time-resolved fluorescence emission, and femtosecond transient absorption spectroscopy as well as a spectrotemporal analysis of the obtained data has been applied. This work presents a new concept for an artificial light-harvesting system positioning the dye units by means of calix[4]arene spacers along a zigzag chain. The investigations start with the syntheses and optical properties of the monochromophoric building blocks and result in an elaborate study on the energy and electron transfer processes occurring after photoexcitation in a comprehensive series of multichromophoric calix[4]arene–perylene bisimide conjugates. Finally, the photophysical properties of a series of compounds containing each two identical PBI units are discussed.
This thesis deals with the isolation and structural elucidation of bioactive naphthylisoquinoline alkaloids and related analogs. The mode of action of the antiplasmodial activity exhibited by the naphthylisoquinoline alkaloids was explored and compared to that of the antimalarial drug chloroquine. Furthermore, the phase 1 and 2 metabolism of dioncophyllines A and C and dioncopeltine A were investigated. In detail the following results have been obtained: • From the leaves of the recently discovered East African liana A. tanzaniensis six naphthylisoquinoline alkaloids were isolated. • The leaves of a botanical yet undescribed Ancistrocladus species, collected by Prof. Dr. V. Mudogo in the Democratic Republic of Congo in the habitat Yeteto near the town Ikela, were analyzed for naphthylisoquinoline alkaloids for the first time. The isolation work led to the first identification of an N,C-coupled naphthyldihydroisoquinoline alkaloid; ancistrocladinium B. Phytochemical investigation of the roots of the Congolese Ancistrocladus species (habitat Yeteto), , afforded five new derivatives of known naphthylisoquinoline alkaloids, namely 5'-O-demethylhamatine, 5'-O-demethylhamatinine, 6-O-demethylancistroealaine A, 6,5'-O,O-didemethylancistroealaine A, and 5-epi-6-O-methylancistrobertsonine A, along with six known naphthylisoquinoline alkaloids. • The antiplasmodial activity guided purification of 60Co irradiated samples containing commercially available naphthylisoquinoline related substances, afforded the isolation of the irradiation products 3,4-dihydro-1-isoquinolinone, 3,4-dihydro-1-isoquinolineamine, and 1,2,3,4-tetrahydro-1,2-diazirino-isoquinoline. The compounds were found to be more active than the starting material, although only exhibiting weak antiplasmodial activity against P. falciparum. • The effect on the absorption spectrum of FPIX due to complex formation with the naphthylisoquinoline alkaloids dioncophyllines A and C, dioncopeltine A korupensamine A, and ancistrocladine was examined by a titration study. Job's plot analyses by UV-spectroscopy determined the stoichiometry for the complex formation of FPIX and naphthylisoquinoline alkaloids to be 2:1. Furthermore, the dissociation constants for the complexation with FPIX were determined for each of the naphthylisoquinoline alkaloids investigated. Dioncophylline C and dioncopeltine A were found to possess dissociation constants, which are comparable to the one reported for the antimalarial drug chloroquine. The ability of ESI to transfer noncovalent solution-phase assemblies intact into the gas phase, was conducted on solution mixtures of naphthylisoquinoline alkaloid and FPIX, as well as on mixtures of chloroquine and FPIX. The mass spectrometry analyses revealed several peaks, which corresponded to the complex formation of FPIX to the respective ligands investigated. The most interesting results obtained were the detection of peaks corresponding to the complex formation between a chelated dimer of FPIX and dioncophylline Cand of peaks corresponding to a double protonated tetramer of FPIX – consisting of two chelated -oxo dimers of FPIX – in complex formation with two molecules of chloroquine. • Two phase 1 metabolism products of dioncophylline A were identified. Coelution in combination with HPLC-MS/MS, NMR, and CD investigations assigned the major metabolic product as 5'-O-demethyldioncophylline A. The minor metabolic product was only present in small amounts, which disabled an unambiguous structural characterization of the compound. However, as deduced from the mass spectrometry analyses and exclusion of a possible metabolic oxidation product by coelution with authentic reference material, the metabolite should possess a 4-hydroxylated isoquinoline portion and is assumed to be represented by structure. Dioncophylline C and dioncopeltine A were found to be stable to phase 1 metabolism reactions caused by rat liver microsomes.
Oxygen-centered radicals are important intermediates in photobiological, mechanistic and synthetic studies. The majority of precursors of reactive oxyl radicals are labile and thus delicate to handle. Therefore N-(alkoxy)-pyridinethiones and N-(Alkoxy)-thiazolethiones have attracted attention as "mild'' photochemical source of alkoxyl radicals, in the last few years. A disadvantage of the pyridine compounds, is their sensibility to daylight. Despite of their similarities, both molecules behave surprisingly different, if photolyzed in the absence of trapping reagents. The pyridinethione compounds undergo highly efficient radical chain reactions under such conditions while the corresponding thiazolethiones react surprisingly sluggish and give rise to several unwanted side products. The properties of both compounds should be understood and optimized in the frame of this work. Additionally new compounds should be suggested that can also be applied in the photochemical alkoxyl radical generation. Some background information about the generation and application of alkoxyl radicals is provided in chapter 2. Electronic excitations and UV/vis spectroscopy together with a description of quantum chemical approaches that are able to calculate such phenomena are outlined in chapter 3. Chapter 4 deals with the description of the vertical excitation spectra. During the validation CASSCF, CASPT2, TD-DFT and RI-CC2 were tested with respect to their ability to describe the vertical excitations in both compounds. The CASPT2 approach gives accurate descriptions of the electronic excitation spectra of all compounds. The time-dependent DFT results are very sensitive on the choice of the functional and a validation of the results should be always done. On the basis of these computations the spectroscopic visible absorption bands of both compounds were assigned to a pi-->pi* transition in the thiohydroxamic acid functionality. In chapter 5 the mechanism of the thermally and the photochemically induced N,O homolysis in both compounds is unveiled. The near UV-induced N,O homolysis will start from the S2 state. The expected relaxation from the S2- to the S1-state and the dissociation process is expected to be very fast in the case of the thiazolethione compound. The potential surfaces of the pyridine compound in contrast point to a slower N,O bond dissociation. Due to the resulting faster dissociation process the excess energy which results from the photochemical activation is quenched only to small amounts. The maximal possible excess energy of the fragments is lower and a quenching is much more likely in the case of the pyridinethione compounds. This explaines the different reactivities of both compounds. For the also already successfully applied precursor system N-(alkoxy)-pyridineones the computed dissociation paths show courses that clearly predict a slow bond dissociation process. Chapter 6 deals with the tuning of the initial excitation wave length of the known pyridinethiones und thiazolethiones. In the first part the effects of substituents on the thiazolethione heterocycle was examined. The UV/vis spectra of 4 and 5 substituted thiazolethiones can be interpreted like the spectrum of the parent compound. The second part of chapter 6 deals with the identification of a substitution pattern on the pyridine heterocycle which induces a blue shift of the photo active band. The computations showed that electron rich and electron poor substituents result the same effects on the electronic excitation spectra. These substituent effects are additive, but the steric orientation of the substituents has to be taken into account. Chapter 7 describes a computer aided design of new alkoxyl radical precursors. Combining the advantages of both compounds the radical formation should be initiated by an irradiation with light at about 350 nm, and the amount of side products during the radical formation process should be small. To achieve this 18 test candidates were obtained by a systematic variation of the parent compound of the thiazolethione precursor. To identify the promising new precursor systems a screening of the lower electronic excitations of all resulting 18 systems was performed with TD-DFT. For promising systems the N,O or P,O dissociation paths, respectively, were analyzed according to the developed model. N-(methoxy)-azaphospholethione and N-(methoxy)-pyrrolethione seem to be the most promising candidates. The computations predict a strong absorption at about 350 nm respectively 320 nm. Due to the amounts of maximal excess energy and the shapes of the potential surfaces of the N,O bond dissociation paths their reactivity should resemble more the behavior of the pyridinethiones.