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1. Bis(1-(4-tolyl)-carboran-2-yl)-(4-tolyl)-borane, a new bis(o-carboranyl)-(R)-borane 1 was synthesised by lithiation of the o-carboranyl precursor and subsequent salt metathesis reaction with (4-tolyl)BBr2. Cyclic voltammetry experiments on 1 show multiple distinct reduction events with a one-electron first reduction. In a selective reduction experiment the corresponding paramagnetic radical anion 1•− was isolated and characterized. Single-crystal structure analyses allow an in-depth comparison of 1, 1•−, their calculated geometries, and the S1 excited state of 1.
2. The choice of backbone linker for ortho-bis-(9-borafluorene)s has a great influence on the LUMO located at the boron centers and therefore the reactivity of the respective compounds. Herein, we report the room temperature rearrangement of 1,2-bis-(9-borafluorenyl-)-ortho-carborane, C2B10H10-1,2-[B(C12H8)]2 ([2a]) featuring o-carborane as the inorganic three-dimensional backbone and the synthesis of 1,2-bis-(9-borafluorenyl-)benzene, C6H4-1,2-[B(C12H8)]2 (2b) its phenylene analog. DFT calculations on the transition state for the rearrangement support an intramolecular C–H bond activation process via an SEAr-like mechanism in [2a], and predicted that the same rearrangement would take place in 2b, but at elevated temperatures, which indeed proved to be the case.
3. We synthesized 4 a julolidine-like pyrenyl-o-carborane, with pyrene substituted at the 2,7-positions on the HOMO/LUMO nodal plane, continuing our research. Using solid state molecular structures, photophysical data, cyclic voltammetry, DFT and TD-DFT calculations we compare o-carborane and the B(mes)2 (mes = 2,4,6-Me3C6H2) as acceptor groups and confirm the julolidine-like donor strength.
This work involves the synthesis and reactivity of pseudohalide-substituted boranes and borylenes. A series of compounds of the type (CAAC)BR2Y (CAAC = cyclic alkyl(amino)carbene; R = H, Br; Y = CN, NCS, PCO) were prepared first. The two-electron reduction of (CAAC)BBr2Y (Y = CN, NCS) in the presence of a second Lewis base L (L = N-heterocyclic carbene) resulted in the formation of the corresponding doubly Lewis base-stabilized pseudohaloborylenes (CAAC)(L)BY. These borylenes show versatile reactivity patterns, including their oxidation to the corresponding radical cations, coordination via the respective pseudohalide substituent to group 6 metal carbonyl complexes, as well as a boron-centered protonation with Brønsted acids to boronium cations. Reduction of (CAAC)BBr2(NCS) in the absence of a second donor ligand, led to the formation of boron-doped thiazolothiazoles via reductive dimerization of two isothiocyanatoborylenes. These B,N,S-heterocycles possess a low degree of aromaticity as well as interesting photophysical properties and can furthermore be protonated as well as hydroborated. Additionally, CAAC adducts of the parent boraphosphaketene (CAAC)BH2(PCO) could be prepared, which readily reacted with boroles [Ph4BR'] (R' = aryl) via decarbonylation in a ring expansion reaction. The obtained 1,2-phosphaborinines represent B,P-isosteres of benzene and consequently could be coordinated to metal carbonyl complexes of the chromium triade via η6-coordination, resulting in new half-sandwich complexes thereof.
An N-heterocyclic-carbene-stabilized diboryne undergoes rapid, high-yielding and catalyst-free hydroamina- tion reactions with primary amines, yielding 1-amino-2-hydro- diborenes, which can be considered boron analogues of enamines. The electronics of the organic substituent at nitrogen influence the structure and further reactivity of the diborene product. With electron-rich anilines, a second hydroamination can occur at the diborene to generate 1,1-diamino-2,2-dihy- drodiboranes. With isopropylamine, the electronic influence of the alkyl substituent upon the diborene leads to an unprece- dented boron-mediated intramolecular N-dearylation reaction of an N-heterocyclic carbene unit.
Reduction of (CAAC)BBr\(_2\)(NCS) (CAAC=cyclic alkyl(amino)carbene) in the presence of a Lewis base L yields tricoordinate (CAAC)LB(NCS) borylenes which undergo reversible E/Z-isomerization. The same reduction in the absence of L yields deep blue, bis(CAAC)-stabilized, boron-doped, aromatic thiazolothiazoles resulting from the dimerization of dicoordinate (CAAC)B(NCS) borylene intermediates.
Photosynthesis is the most fundamental process of life on earth. The biological production of oxygen in plant photosynthesis occurs in photosystem II (PSII). Here two water molecules are coupled in a four-electron oxidation to one O2 molecule, catalyzed by a tetranuclear manganese complex, known as the oxygen-evolving complex (OEC). In this thesis, density-functional theory (DFT) methods were validated and subsequently employed to study structures, spin-density distributions and EPR parameters of mono-, di-, and tetranuclear complexes with regard to the OEC. The goal was to draw conclusions on the molecular and electronic structure of the OEC.
Quantum chemical modeling of electron paramagnetic resonance (EPR) parameters, in combination with data from the modern high-field/high-frequency EPR (HF-EPR) techniques, constitutes an invaluable analytical tool for gaining insight into radical-protein interactions, which determine the specificity and directionality of the radical-mediated biochemical processes. This thesis reports a series of density functional (DFT) studies on EPR parameters of several biologically relevant radicals and a series of molecular devices inspired by radical-protein interaction in photosystem I (PS-I). We demonstrate our methodology’s accuracy and capacity to provide insight into the in vivo environment and reactivity of bioradicals. Our DFT approach for the calculation of electronic g-tensors has been applied to semiquinone radical anions in the different protein environments of photosynthetic reaction centers. Supermolecular models have been constructed, based on combined crystallographic and quantum chemical structure data, for the QA and QB active sites of bacterial reaction centers, for the A1 site of PS-I, as well as for ubisemiquinone in frozen 2-propanol. After scaling of the computed gx components by 0.92, both gx and gy components computed at gradient-corrected DFT level with accurate spin-orbit operators agree with HF-EPR reference data essentially to within experimental accuracy in all four systems studied. The influence of the various semiquinone-protein non-covalent interactions has been studied by successive removal of individual residues from the models. The effects of hydrogen bonding to the two carbonyl oxygen atoms of the semiquinones was found to be nonadditive, due to compensating spin-polarization effects. The effects of tryptophan-semiquinone -stacking are different for QA and A1 sites. This may be traced back to a different alignment of the interacting fragments and to differential spin polarization. In the next part of this work our DFT methodology has been applied to the semiquinone in the environment of the “high-affinity” binding site of quinol oxidase (QH site). Recent multi-frequency EPR studies of the QH binding site of quinol oxidase have suggested a very asymmetric hydrogen-bonding environment for the semiquinone radical anion state. Single-sided hydrogen bonding to the O1 carbonyl position was one of the proposals, which contrasts with some previous experimental indications. The density functional calculations of the EPR parameters (g-tensors, 13C, 1H, and 17O hyperfine tensors) for a wide variety of supermolecular model complexes have been used to provide insight into the detailed relations between structure, environment and EPR parameters of ubisemiquinone radical anions. A single-sided binding model is not able to account for the experimentally observed low gx component of the g-tensor nor for the observed magnitude of the asymmetry of the 13C carbonyl hyperfine coupling (HFC) tensors. Based on the detailed comparison between computation and experiment, a model with two hydrogen bonds to O1 and one hydrogen bond to O4 was suggested for the QH site, but a model with one more hydrogen bond on each side could not be excluded. Additionally, several general conclusions on the interrelations between EPR parameters and hydrogen bond patterns of ubisemiquinones in proteins were provided. The computational studies related to the mechanism of electron transfer in PS-I gave an impetus to the theoretical design, based on quantum-chemical calculations, of relatively small rotational molecular motors made up from intramolecularly connected dyads consisting of a quinone unit and a pyrrole or indole moiety. It was shown computationally for several systems, depending on the length and attachment points of the interconnecting chains, that a reduction of the quinone to the semiquinone radical anion or quinolate dianion states leads to a reversible intramolecular reorientation from a -stacked to a T-stacked arrangement. In the rearranged structures, a hydrogen bond from the pyrrole or indole N-H function to the semiquinone or quinolate -system is created upon reduction. In some systems, hydrogen bonds to the semiquinone or quinolate oxygen atoms are partly feasible and will be preferred over T-stacking. It was shown that the intramolecular interactions modify the quinone redox potentials. The electronic g-tensors computed for the semiquinone states reflected characteristically the presence and nature of hydrogen bonds to the semiquinone and were suggested as suitable EPR spectroscopic probes for the preferred structures. Intramolecular proton transfer was observed to be possible in the dianionic state. In contrast to semiquinones, which represent paramagnetic states of enzyme cofactors, glycyl radicals are genuine protein radicals. As a step towards an in-depth understanding of the EPR parameters of glycyl radicals in proteins, the hyperfine- tensors and, particularly, the g-tensor of N-acetylglcyl in the environment of a single crystal of N-acetylglycine have been studied by systematic state-of-the-art quantum chemical calculations on various suitable model systems. The quantitative computation of the g-tensors for such glycyl-derived radicals is a veritable challenge, mainly due to the very small g-anisotropy combined with a non-symmetrical, delocalized spin-density distribution and several atoms with comparable spin-orbit contributions to the g-tensors. The choice of gauge origin of the magnetic vector potential, and of approximate spin-orbit operators, both turn out to be more critical than found in previous studies of g-tensors for organic radicals. Environmental effects, included by supermolecular hydrogen-bonded models, were found to be moderate, due to a partial compensation between the influences from intramolecular and intermolecular hydrogen bonds. The largest effects on the g-tensor are caused by the conformation of the radical. The DFT methods employed systematically overestimate both the gx and gy components of the g-tensor. This is important for investigations on the protein-glycyl radicals (see next paragraph). The 1H and 13C hyperfine couplings depend only slightly on the supermolecular model chosen and appear less sensitive probes of detailed structure and environment. The number of enzymes that require a glycyl-based radical for their function is growing. Here we provide systematic quantum-chemical studies of spin-density distributions, electronic g-tensors, and hyperfine couplings of various models of protein-bound glycyl radicals. Similarly to what was found for N-acetylglycyl (see previous paragraph), the small g-anisotropy for this delocalized, unsymmetrical system presents appreciable challenges to state-of-the-art computational methodology. This pertains to the quality of structure optimization, as well as to the choice of spin-orbit Hamiltonian and gauge origin of the magnetic vector potential. Environmental effects due to hydrogen bonding are complicated and depend in a subtle fashion on the different intramolecular hydrogen bonding for different conformations of the radical. Indeed, the conformation has the largest overall effect on the computed g-tensors (less so on the hyperfine-tensors). We discuss this in the context of different g-tensors obtained by recent HF-EPR measurements for three different enzymes. Based on results of calibration study for N-acetylglycyl, we support that the glycyl radical observed for E.coli anaerobic ribonucleotide reductase (ARNR) has a fully extended conformation, which differs from those of the corresponding radicals in pyruvate formate-lyase (PFL) or benzylsuccinate synthase (BSS).
In this work we utilized Density Functional Theory to calculate EPR parameters and spin-density distributions of several transition metal complexes. To demonstrate the performance of our theoretical approach several validation studies were performed (Chapters 3-5). In contrast, the last three chapters of the thesis deal with specific chemical problems regarding several classes of biologically relevant transition metal complexes.