TY - THES A1 - Noll, Niklas T1 - Second Coordination Sphere Engineering in Macrocyclic Ruthenium Water Oxidation Catalysts T1 - Gestaltung der sekundären Koordinationssphäre von makrozyklischen Ruthenium Wasseroxidationskatalysatoren N2 - About 2.4 billion years ago, nature has fundamentally revolutionized life on earth by inventing the multi-subunit protein complex photosystem II, the only molecular machine in nature that catalyzes the thermodynamically demanding photosynthetic splitting of water into oxygen and reducing equivalents. Nature chose a distorted Mn4CaO5 cluster as catalyst, better known as oxygen-evolving complex (OEC), thus recognizing the need for transition metals to achieve high-performance catalysts. The curiosity has always driven mankind to mimic nature’s achievements, but the performance of natural enzymes such as the oxygen-evolving complex in photosystem II remain commonly unmatched. An important role in fine-tuning and regulating the activity of natural enzymes is attributed to the surrounding protein domain, which facilitates substrate preorganization within well-defined nanoenvironments. In light of growing energy demands and the depletion of fossil fuels, the unparalleled efficiency of natural photosynthesis inspires chemists to artificially mimic its natural counterpart to generate hydrogen as a ‘solar fuel’ through the light-driven splitting of water. As a result, significant efforts have been devoted in recent decades to develop molecular water oxidation catalysts based on earth-abundant transition metals and the discovery of the Ru(bda) (bda: 2,2’ bipyridine-6,6’-dicarboxylate) catalyst family enabled activities comparable to the natural OEC. Similar to the natural archetypes, the design of homogeneous catalysts that interplay judiciously with the second coordination sphere of the outer ligand framework proved to be a promising concept for catalyst design. In this present thesis, novel supramolecular design approaches for enzyme like activation of substrate water molecules for the challenging oxidative water splitting reaction were established via tailor-made engineering of the secondary ligand environment of macrocyclic Ru(bda) catalysts. N2 - Vor etwa 2.4 Milliarden Jahren hat die Natur das Leben auf der Erde mit der Entwicklung des mehrgliedrigen Proteinkomplexes Photosystem II grundlegend revolutioniert. Dieser stellt die einzige molekulare Maschine in der Natur dar, die die thermodynamisch anspruchsvolle photosynthetische Spaltung von Wasser in Sauerstoff und reduzierende Äquivalente katalysieren kann. Als Katalyator hat die Natur hierfür ein verzerrtes Mn4CaO5-Cluster ausgewählt, welcher besser bekannt ist als Sauerstoff-produzierender Komplex (OEC, engl.: oxygen-evolving complex). Damit wird die Notwendigkeit von Übergangsmetallen als leistungsfähige Katalysatoren belegt. Die Wissbegierde hat die Menschheit schon immer dazu angetrieben, die Errungenschaften der Natur zu imitieren. Dennoch bleiben die Leistungen natürlicher Enzyme wie die des OEC in Photosystem II häufig unerreicht. Eine wichtige Rolle bei der Feinabstimmung und Regulierung der Aktivität natürlicher Enzyme nimmt die umliegende Proteindomäne ein, die die Vororganisation der Substrate in einer genau definierten Nanoumgebung ermöglicht. Angesichts des wachsenden Energiebedarfs und der Erschöpfung von fossilen Brennstoffen werden Chemiker von der unvergleichlichen Effizienz der natürlichen Photosynthese zu deren künstlichen Nachahmung inspiriert, damit Wasserstoff als "solarer Brennstoff" durch die lichtgetriebene Spaltung von Wasser erzeugt werden kann. Infolgedessen wurden in den letzten Jahrzehnten erhebliche Anstrengungen in die Entwicklung molekularer Wasseroxidationskatalysatoren (WOKs) auf der Basis von Übergangsmetallen unternommen, wobei mit der Entdeckung der Katalysatorfamilie Ru(bda) (bda: 2,2'-Bipyridin-6,6'-dicarboxylat) Aktivitäten vergleichbar mit der des natürlichen OEC realisiert wurden. Als vielversprechendes Konzept für die Entwicklung von Katalysatoren erwies sich die Konstruktion homogener Katalysatoren, die, ähnlich zu den natürlichen Vorbildern, gezielt mit der zweiten Koordinationssphäre eines äußeren Liganden interagieren. In der hier vorliegenden Arbeit wurden neuartige supramolekulare Konzepte zur enzymartigen Aktivierung von Wassermolekülen entwickelt. Hierbei sollte durch eine maßgeschneiderte Konstruktion der sekundären Ligandenumgebung von makrozyklischen Ru(bda)-Katalysatoren die anspruchsvolle oxidative Wasserspaltungsreaktion begünstigt werden. KW - Katalyse KW - Metallosupramolekulare Chemie KW - Wasseroxidation KW - Metallosupramolecular chemistry KW - Catalysis KW - Water Oxidation KW - Second coordination sphere engineering KW - Ruthenium complexes KW - Ruthenium Komplexe Y1 - 2023 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-305332 ER - TY - JOUR A1 - Noll, Niklas A1 - Groß, Tobias A1 - Shoyama, Kazutaka A1 - Beuerle, Florian A1 - Würthner, Frank T1 - Folding‐Induced Promotion of Proton‐Coupled Electron Transfers via Proximal Base for Light‐Driven Water Oxidation JF - Angewandte Chemie International Edition N2 - Proton‐coupled electron‐transfer (PCET) processes play a key role in biocatalytic energy conversion and storage, for example, photosynthesis or nitrogen fixation. Here, we report a series of bipyridine‐containing di‐ to tetranuclear Ru(bda) macrocycles 2 C–4 C (bda: 2,2′‐bipyridine‐6,6′‐dicarboxylate) to promote O−O bond formation. In photocatalytic water oxidation under neutral conditions, all complexes 2 C–4 C prevail in a folded conformation that support the water nucleophilic attack (WNA) pathway with remarkable turnover frequencies of up to 15.5 s\(^{−1}\) per Ru unit respectively. Single‐crystal X‐ray analysis revealed an increased tendency for intramolecular π‐π stacking and preorganization of the proximal bases close to the active centers for the larger macrocycles. H/D kinetic isotope effect studies and electrochemical data demonstrate the key role of the proximal bipyridines as proton acceptors in lowering the activation barrier for the crucial nucleophilic attack of H\(_{2}\)O in the WNA mechanism. KW - artificial photosynthesis KW - folded macrocyles KW - homogeneous catalysis KW - photocatalysis KW - Ruthenium complexes Y1 - 2023 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-312020 VL - 62 IS - 7 ER - TY - JOUR A1 - Noll, Niklas A1 - Krause, Ana-Maria A1 - Beuerle, Florian A1 - Würthner, Frank T1 - Enzyme-like water preorganization in a synthetic molecular cleft for homogeneous water oxidation catalysis JF - Nature Catalysis N2 - Inspired by the proficiency of natural enzymes, mimicking of nanoenvironments for precise substrate preorganisation is a promising strategy in catalyst design. However, artificial examples of enzyme-like activation of H\(_2\)O molecules for the challenging oxidative water splitting reaction are hardly explored. Here, we introduce a mononuclear Ru(bda) complex (M1, bda: 2,2’-bipyridine-6,6’-dicarboxylate) equipped with a bipyridine-functionalized ligand to preorganize H\(_2\)O molecules in front of the metal center as in enzymatic clefts. The confined pocket of M1 accelerates chemically driven water oxidation at pH 1 by facilitating a water nucleophilic attack pathway with a remarkable turnover frequency of 140 s\(^{−1}\) that is comparable to the oxygen-evolving complex of photosystem II. Single crystal X-ray analysis of M1 under catalytic conditions allowed the observation of a 7th H\(_2\)O ligand directly coordinated to a RuIII center. Via a well-defined hydrogen-bonding network, another H\(_2\)O substrate is preorganized for the crucial O–O bond formation via nucleophilic attack. KW - water oxidation KW - enzyme KW - catalysis KW - molecular KW - catalyst synthesis KW - catalytic mechanisms KW - homogeneous catalysis KW - photocatalysis KW - supramolecular chemistry Y1 - 2022 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-302897 N1 - This version of the article has been accepted for publication, after peer review and is subject to Springer Nature’s AM terms of use (https://www.springernature.com/gp/open-research/policies/accepted-manuscript-terms), but is not the Version of Record and does not reflect post-acceptance improvements, or any corrections. The Version of Record is available online at: https://doi.org/10.1038/s41929-022-00843-x ET - accepted version ER - TY - JOUR A1 - Noll, Niklas A1 - Würthner, Frank T1 - Bioinspired water preorganization in confined space for efficient water oxidation catalysis in metallosupramolecular ruthenium architectures JF - Accounts of Chemical Research N2 - Conspectus Nature has established a sustainable way to maintain aerobic life on earth by inventing one of the most sophisticated biological processes, namely, natural photosynthesis, which delivers us with organic matter and molecular oxygen derived from the two abundant resources sunlight and water. The thermodynamically demanding photosynthetic water splitting is catalyzed by the oxygen-evolving complex in photosystem II (OEC-PSII), which comprises a distorted tetramanganese–calcium cluster (CaMn\(_4\)O\(_5\)) as catalytic core. As an ubiquitous concept for fine-tuning and regulating the reactivity of the active site of metalloenzymes, the surrounding protein domain creates a sophisticated environment that promotes substrate preorganization through secondary, noncovalent interactions such as hydrogen bonding or electrostatic interactions. Based on the high-resolution X-ray structure of PSII, several water channels were identified near the active site, which are filled with extensive hydrogen-bonding networks of preorganized water molecules, connecting the OEC with the protein surface. As an integral part of the outer coordination sphere of natural metalloenzymes, these channels control the substrate and product delivery, carefully regulate the proton flow by promoting pivotal proton-coupled electron transfer processes, and simultaneously stabilize short-lived oxidized intermediates, thus highlighting the importance of an ordered water network for the remarkable efficiency of the natural OEC. Transferring this concept from nature to the engineering of artificial metal catalysts for fuel production has fostered the fascinating field of metallosupramolecular chemistry by generating defined cavities that conceptually mimic enzymatic pockets. However, the application of supramolecular approaches to generate artificial water oxidation catalysts remained scarce prior to our initial reports, since such molecular design strategies for efficient activation of substrate water molecules in confined nanoenvironments were lacking. In this Account, we describe our research efforts on combining the state-of-the art Ru(bda) catalytic framework with structurally programmed ditopic ligands to guide the water oxidation process in defined metallosupramolecular assemblies in spatial proximity. We will elucidate the governing factors that control the quality of hydrogen-bonding water networks in multinuclear cavities of varying sizes and geometries to obtain high-performance, state-of-the-art water oxidation catalysts. Pushing the boundaries of artificial catalyst design, embedding a single catalytic Ru center into a well-defined molecular pocket enabled sophisticated water preorganization in front of the active site through an encoded basic recognition site, resulting in high catalytic rates comparable to those of the natural counterpart OEC-PSII. To fully explore their potential for solar fuel devices, the suitability of our metallosupramolecular assemblies was demonstrated under (electro)chemical and photocatalytic water oxidation conditions. In addition, testing the limits of structural diversity allowed the fabrication of self-assembled linear coordination oligomers as novel photocatalytic materials and long-range ordered covalent organic framework (COF) materials as recyclable and long-term stable solid-state materials for future applications. KW - catalysts KW - catalytic activity KW - ligands KW - macrocycles KW - water oxidation KW - ruthenium Y1 - 2024 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-361232 SN - 0001-4842 VL - 57 IS - 10 ER - TY - JOUR A1 - Würthner, Frank A1 - Noll, Niklas T1 - A Calix[4]arene‐Based Cyclic Dinuclear Ruthenium Complex for Light‐Driven Catalytic Water Oxidation JF - Chemistry - A European Journal N2 - A cyclic dinuclear ruthenium(bda) (bda: 2,2’‐bipyridine‐6,6’‐dicarboxylate) complex equipped with oligo(ethylene glycol)‐functionalized axial calix[4]arene ligands has been synthesized for homogenous catalytic water oxidation. This novel Ru(bda) macrocycle showed significantly increased catalytic activity in chemical and photocatalytic water oxidation compared to the archetype mononuclear reference [Ru(bda)(pic)\(_2\)]. Kinetic investigations, including kinetic isotope effect studies, disclosed a unimolecular water nucleophilic attack mechanism of this novel dinuclear water oxidation catalyst (WOC) under the involvement of the second coordination sphere. Photocatalytic water oxidation with this cyclic dinuclear Ru complex using [Ru(bpy)\(_3\)]Cl\(_2\) as a standard photosensitizer revealed a turnover frequency of 15.5 s\(^{−1}\) and a turnover number of 460. This so far highest photocatalytic performance reported for a Ru(bda) complex underlines the potential of this water‐soluble WOC for artificial photosynthesis. KW - water KW - oxidation KW - ruthenium KW - dinuclear KW - catalytic KW - artificial photosynthesis KW - homogenous catalysis KW - photocatalysis KW - ruthenium complexes KW - water oxidation Y1 - 2021 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-230030 UR - https://chemistry-europe.onlinelibrary.wiley.com/doi/10.1002/chem.202004486 VL - 27 IS - 1 ER -