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21	MULTI-ELECTRON REDOX CHEMISTRY WITH THORIUM AND CERIUM IMINOQUINONE COMPLEXES TO FORM RARE MULTIPLE BONDS Ramitha Y.P.R. Dissanayake Mudiyanselage (14189420) 29 November 2022 (has links) <p>Thorium complexes primarily exist in the thermodynamically stable (IV) oxidation state with only a few low-valent thorium(III) and thorium(II) complexes having been isolated. As a result, redox chemistry with thorium at the metal center is synthetically challenging without carefully selected ligand systems. This redox-restricted nature of thorium(IV) makes redox-active ligands (RALs) an attractive option to facilitate multi-electron redox chemistry with thorium. In this work, first, a series of thorium(IV) complexes featuring the redox-active iminoquinone ligand and its derivatives, including the iminosemiquinone and amidophenolate species, were synthesized and characterized. Rare thorium oxygen multiple bonds were then accessed by exploiting the RALs on the thorium center and using dioxygen in dry air. Other oxidation chemistry was attempted with the thorium amidophenolate complexes as well. Second, armed with the knowledge of synthesizing multiple bonds with thorium(IV) complexes, similar chemistry was explored with cerium as it is in the same group as thorium. A series of cerium(III) and cerium(IV) complexes featuring the redox-active iminoquinone ligand and its derivatives were synthesized. Oxidation chemistry was explored with the cerium amidophenolate complexes and a rare cerium oxo was isolated. Finally, with interest in expanding and addressing a gap in the literature related to the synthesis, characterization, and utility of thorium alkyls, several tetrabenzylthorium complexes were synthesized, characterized, and some reactivity was explored. A highlight of this work involved the isolation of the first crystal structure of ligand and solvent free tetrabenzylthorium since its first synthesis in 1974. Full spectroscopic and structural characterization of the complexes was performed via <sup>1</sup>H NMR spectroscopy, X-ray crystallography, EPR spectroscopy, electronic absorption spectroscopy, and SQUID magnetometry, which all confirmed the identity and electronic structure of these complexes. </p> Crystallography F-block chemistry Organometallic chemistry thorium cerium iminoquinone redox-active redox chemistry radical oxo
22	Design and analysis of an electronically switchable ion exchange system Kannappan, Ramakrishnan 21 June 2010 (has links) Metal contamination is a considerable environmental problem because metals are persistent contaminants. Ion exchange is one of the most commonly used treatment options for trace metal removal. This research develops and evaluates a redox active modified ion exchange system that has the potential to reduce the ionic strength of ion exchange regeneration streams. Poly-L-cysteine (PLC) was selected as the redox active, adsorbing functional group on the surface of a reticulated vitreous carbon (RVC) electrode. PLC is an excellent soft acid metal chelator and is unique in that its thiol groups can form disulfide bonds with each other. The reduction of available thiols changes the metal binding capacity of the peptide since the thiol is the primary binding group. RVC provides a macroporous conductive monolithic resin to support the peptide. An experimental apparatus was designed to study the properties of this system and estimate performance. Distinct oxidized and reduced states of PLC on the surface of the RVC were confirmed by changes in metal binding characteristics. Adsorption edges showed a sharper pH dependence for the reduced electrode compared to the oxidized electrode from pH 3-7. Adsorption isotherms performed at pH 7 showed increased capacity for the reduced electrode. The change was reversible by chemical and electrical reduction. This difference was confirmed at the molecular level with Cd- EXAFS of oxidized and reduced electrodes. A greater degree of cadmium-sulfur coordination was observed on the reduced electrode and a greater cadmium-oxygen coordination was apparant on an oxidized electrode. A multidentate adsorption model was developed to model the pH dependent behavior of cadmium adsorption on the PLC-RVC surface. Nickel adsorption showed increased adsorption in the oxidized state. The most likely explanation is increased carboxylate complexation. The electronically switchable ion exchange system (ESIE) provides a framework for modifying traditional ion exchange processes. The system has 5 to 10 times less specifc capacity than current ion exchange systems, but uses solutions 10-100 times lower in ionic strength for regeneration. Further studies on the effect of ionic strength on adsorption and current usage are necessary to compare the cost of the ESIE process to traditional ion exchange. / text Metal contamination Ion exchange Poly-L-cysteine Reticulated vitreous carbon Redox active modified ion exchange Metal binding Adsorption
23	Mechanically interlocked and redox switchable molecules at surfaces Rahman, Habibur January 2013 (has links) This thesis explores the surface assembly of mechanically interlocked molecular architectures at gold surfaces for potential applications in molecular switches, anion sensing and stimuli (redox and optical) responsive molecular films. <b>Chapter One</b> introduces the field of mechanically interlocked molecules focusing on rotaxane and catenane surface assemblies in the form of single molecule thick self-assembled monolayers. A review of the surface-attached characteristics of mechanically interlocked molecules is given before exploring specific anion template directed strategies for their construction. The potential to incorporate both redox-active and optically-active functional groups within these mechanically interlocked molecules is also discussed. <b>Chapter Two</b> provides the experimental details and procedures employed in this thesis to characterise the molecular systems under investigation. <b>Chapter Three</b> introduces several surface characterisation techniques such as; ellipsometry, contact angle, X-ray reflectivity and X-ray photoelectron spectroscopy, with a particular focus of applying these tools to probe the surface co-conformation of switchable and interlocked molecules at surfaces. Electroanalytical techniques such as cyclic voltammetry, chronoamperometry and electrical impedance spectroscopy are also introduced. <b>Chapter Four</b> details the surface assembly of a series of ferrocene containing anion templated catenane self-assembled monolayers on gold. Detailed electrochemical and angle resolved X- ray photoelectron spectroscopy characterisation elucidates the co-conformation upon surface attachment. <b>Chapter Five</b> details the anion templated surface assembly of a redox-active rotaxane self- assembled monolayer on gold. Subsequent electroanalysis and X-ray photoelectron spectroscopy characterisation confirms the structural integrity of the film and a possible co- conformation at the surface is discussed. <b>Chapter Six</b> describes efforts towards constructing optically responsive hybrid d-f lanthanide containing mechanically interlocked molecules. Initial work focuses on switching characteristics of a redox switchable antennae and its ability to modulate the luminescence of a series of lanthanide complexes in solution. Subsequent surface attachment of the lanthanide complexes in the form of emissive self-assembled monolayers is also investigated. 541
24	Facilitating Multi-Electron Chemistry in the F-Block Using Iminoquinone Ligands Ezra J Coughlin (6629939) 11 June 2019 (has links) <div><div><div><p>The chemistry of the f-block is relatively unknown when compared to the rest of the periodic table. Transition metals and main group elements have enjoyed thorough study and development over the last 200 years, while many of the lanthanides and actinides weren’t even discovered until the 1940’s. This is troublesome, as knowledge of these elements is critical for environmental, industrial and technological advances. Understanding bonding motifs and reactivity pathways is fundamental to advancing the field of f-block chemistry. The use of redox- active ligands has aided in the construction of new bonding modes and discovery of new reaction pathways by providing electrons for these transformations. A particularly successful partnership is formed when redox-active ligands are combined with lanthanides, as these elements are usually considered redox-restricted. A series of lanthanide complexes featuring the iminoquinone ligand in three oxidation states will be discussed. The use of the ligands as a source of electrons for reactivity is also described, with new bonding motifs for lanthanides being realized. The iminoquinone ligand can also serve to break bonds. The uranyl (UO22+) ion is notoriously difficult to handle due to its strong U-O multiple bonds. To overcome this, we developed a series of uranyl complexes and studied the ability of the iminoquinone ligand to serve as an electron source for reduction of uranium, with concomitant U-O bond cleavage.</p></div></div></div> Inorganic Chemistry f-Block Chemistry Structural Chemistry and Spectroscopy Organometallic Chemistry Chemistry f-block elements redox-active ligand
25	Conception et réactivité de nouveaux complexes de lanthanides et de cobalt contenant des ligands rédox-actifs : application aux réductions multi-électroniques / Synthesis and reactivity of new complexes of lanthanides and cobalt bearing redox-active ligands for multi-electron reductions Guidal, Valentin 27 October 2014 (has links) La capacité des complexes de lanthanides divalents à promouvoir des réductions inhabituelles suscite actuellement un grand intérêt, tout particulièrement leur aptitude à activer des petites molécules telles CO2 et N2 dans des conditions douces. Les ions lanthanides, de par leurs propriétés de coordination tout à fait uniques pourraient offrir une alternative aux métaux de transition couramment utilisés pour la conception de catalyseurs. Cependant, comparativement aux métaux du bloc d, la chimie de coordination des lanthanides est exclusivement dominée par des transferts mono-électroniques qui impliquent uniquement les capacités rédox du centre lanthanide. C'est pourquoi le développement de nouveaux complexes de lanthanides capables de réaliser des réductions poly-électroniques est particulièrement intéressant. Dans un premier temps, nous avons utilisé des ligands rédox-actifs de type base de Schiff π-conjuguées pour étudier la chimie des ions lanthanides en réduction. Cela nous a permis d'isoler des complexes dans lesquels deux ou quatre électrons sont stockés sur le ligand via la formation de liaisons C-C. Ces mêmes liaisons sont rompues en présence d'agents oxydants et les électrons sont libérés pour réaliser des transformations multi-électroniques. Ce procédé a été observé pour des bases de Schiff tridentates et tétradentates, ce qui nous a permis de moduler les propriétés rédox des composés. La réactivité avec CO2 des complexes synthétisés a également été étudiée et nous avons identifié des complexes de néodyme capables de réduire le CO2. Dans un second temps, nous nous sommes intéressés à l'étude de complexes de cobalt contenant des ligands rédox-actifs de type base de Schiff π-conjuguées capables de stocker des électrons sous forme de liaisons C-C. Ce système, déjà étudié dans les années 1990, avait démontré sa capacité à activer le CO2. Avec l'intention de déterminer l'espèce active dans la réaction avec CO2, nous avons revisité ce système et mis en lumière un équilibre d'isomérie rédox entre un complexe de Co(I) et un complexe de Co(II) où un électron peut être localisé sur le métal ou sur le ligand. Nous nous sommes également intéressés aux paramètres qui régissent cet équilibre. En particulier, nous avons étudié l'influence de l'architecture du ligand sur les propriétés rédox des complexes de cobalt. Ces études offrent de nouvelles perspectives pour le développement de complexes capables d'effectuer la réduction électrocatalytique du CO2. / The redox chemistry of lanthanide complexes is attracting increasing interest because of the potential of divalent lanthanide complexes to promote unusual redox chemistry. For example they are able to activate small molecules such as CO2 and N2 in mild conditions. Due to the unique coordination and bonding properties of the lanthanide ions, their compounds could provide an attractive alternative to transition metals for the catalytic transformation of small molecules. However, metal-based multi-electron processes remain uncommon in lanthanide chemistry especially in comparison with the d-block metals; the chemistry of low-valent lanthanides being dominated by single-electron transfers. In this context, the first aim of this project was to investigate the association of lanthanides with a redox-active ligand acting as an independent electron reservoir within the same molecule. Accordingly, we examined the use of highly π-delocalized Schiff base ligands to study the reductive chemistry of lanthanide ions. This led to the isolation of electron-rich complexes which are stabilized by storing two or four electrons on the ligands through the formation of C-C bonds. Interestingly, these C-C bonds can be cleaved by oxidizing agents and the electrons released can participate in multi-electron redox reactions. This process was observed within different tridentate and tetradentate Schiff-base ligand scaffolds, allowing a tuning of the properties of the compounds. The ability of these complexes to react with CO2 has been studied, which lead to the identification of some neodymium complexes capable of reducing CO2. The second part of this work was dedicated to the study of cobalt complexes bearing redox-active and highly π-delocalized Schiff base ligands able to store electrons through the formation of C-C bonds. Seminal studies on Schiff base complexes of cobalt had been carried out in the 1990's and they demonstrated the ability of these complexes to activate CO2. With the aim to identify the active species responsible for CO2 activation, we have revisited these systems and highlighted a redox-isomeric equilibrium between a Co(I) and a Co(II) complexes where the electron can be localized on the cobalt or on the ligand. We also investigated the parameters influencing this equilibrium. In particular we have investigated the effect of the ligand architecture on the redox reactivity of cobalt complexes. Such studies pave the way to the development of new complexes for the electrocatlytic reduction of CO2. Lanthanides Cobalt Ligand rédox-actif Base de Schiff Dioxyde de carbone Réduction Lanthanides Cobalt Redox-active ligand Schiff base Carbon dioxide Reduction 540
26	Synthesis and study of redox-active molecular nanomagnets / Synthèse et étude de nanoaimants moléculaires redox-actifs Ma, Xiaozhou 11 September 2019 (has links) Ce travail de thèse portait sur la synthèse et l'étude de complexes magnétiques redox-actifs comme prototypes pour la conception d'aimants moléculaires à haute température. L'activité redox est assurée par le ligand pontant, qui peut moduler et parfois améliorer significativement les propriétés magnétiques. Après un chapitre d'introduction présentant les derniers développements dans le domaine des matériaux magnétiques moléculaires, un accent particulier est mis sur l'importance d'avoir un fort couplage d'échange magnétique J entre les porteurs de spin. Une étude bibliographique présentant deux approches émergentes pour augmenter J dans les composés polynucléaires est également présentée et discutée. Le chapitre 2 présente les synthèses et caractérisations de complexes dinucléaires [M2(tphz)(tpy)2](PF6)n (M = Co(II) ou Ni(II); n = 4, 3, 2, tphz = tétrapyridophénazine, tpy = terpyridine) construits à partir de ligands pontant (tphz) et bloquant (tpy) fortement coordinants et redox-actifs. Les études approfondies de ces composés montrent que le ligand pontant redox-actif peut être utilisé comme un outil de choix pour promouvoir une délocalisation des spins, de forts couplages magnétiques, ainsi que de la commutabilité. L’analyse des résultats obtenus permet également de mieux comprendre les paramètres clés pour l’élaboration de systèmes fortement couplés magnétiquement. Dans le prolongement de ce travail visant à sélectionner les meilleurs composants pour la conception rationnelle d'aimants moléculaires à haute température, le chapitre 3 décrit une nouvelle série de complexes mononucléaires [Cr(III)(tphz)(tpy)](CF3SO3)n (n = 3, 2, 1). Les complexes mono- et doublement réduits présentent des interactions magnétiques remarquablement fortes entre les ions métalliques et les ligands radicalaires, et pourraient servir d'unités magnétiques intéressantes pour la conception d'aimants de plus hautes nucléarités. / The thesis work aims at the synthesis and study of redox-active magnetic molecules as prototypes towards the design of molecule-based magnets with high operating temperature, a prerequisite for technological applications. The redox activity is provided by the bridging ligand, which could tune and sometimes enhance significantly the magnetic properties of the resulting molecular architectures. After an introduction chapter presenting the latest developments in the field of molecule-based magnetic materials, special emphasis is given on the importance of having large magnetic exchange coupling J between the spin carriers to reach high operating temperature. This is supported by a bibliographic study concerning two emerging approach to enhance J values in polynuclear compounds. Chapter 2 presents the syntheses and characterizations of dinuclear M(II) complexes [M2(tphz)(tpy)2](PF6)n (M = Co or Ni; n = 4, 3, 2, tphz = tetrapyridophenazine) built by using strongly complexing, redox-active bridging ligand (tphz), and terpyridine (tpy) as capping ligands. The extensive studies on these compounds show that the redox-active bridging ligand can be used as a tool to promote spin delocalization, high spin complexes and magnetic multi-switchability. Importantly the work reveals the key parameters towards building strongly magnetically coupled systems. As a continuation research of finding the best magnetic components for the rational design of high temperature molecule-based magnets, Chapter 3 describes a new series of [Cr(III)(tphz)(tpy)](CF3SO3)n (n = 3, 2, 1) mononuclear complexes. Both the mono and doubly-reduced complexes show remarkable magnetic interactions between metal center and radical ligands, which could further act as interesting magnetic units for the design of higher nuclearities magnets. Matériaux magnétiques moléculaires Ligand redox-Actif Couplage magnétique Radical Commutabilité magnétique Molecule-Based magnetic material Redox-Active ligand Magnetic exchange coupling Radical Magnetic multi-Switchability
27	Synthèse de nouveaux complexes aryl-palladium et aryl-or pour le marquage par du monoxyde de carbone de composés bioconjugués supportés et pour des réactions de couplages / Synthesis of new aryl-palladium and aryl-gold complexes for the carbon monoxide labeling of supported bioconjugated compounds and for coupling reactions Tabey, Alexis 28 February 2019 (has links) L’essor de la chimie organométallique a permis de développer de nouvelles possibilités dans le domaine du diagnostic médical, en particulier pour la tomographie à émission de positrons (TEP). Ainsi, de nouvelles méthodologies ont été développées pour permettre la synthèse de bio-traceurs avec le marquage au 11C comme étape finale. Dans ce contexte, notre équipe a récemment développé une nouvelle méthodologie pour marquer une large variété de substrats dans des conditions standards de carbonylation et ces travaux de thèse présentent une nouvelle stratégie de synthèse impliquant la préformation de complexes palladiés supportées. Ainsi, leurs ancrages préalables sur une résine facilitent la réaction de carbonylation en simplifiant leur purification. De nouveaux complexes à base de palladium ont aussi été synthétisés et étudiés pour envisager de potentielles applications en catalyse photorédox. Enfin le développement de nouvelles stratégies de couplage impliquant des intermédiaires d’or (III) étant un domaine en plein expansion, notamment lorsqu’elles combinent catalyse à l’or et photorédox, il a été envisagé de synthétiser de nouveaux complexes d’or afin d’étudier les mécanismes réactionnels impliqués dans ces couplages et d’évaluer les possibilités de synthèse de composés biaryliques atropoisomériques. / The growth of organometallic chemistry has allowed numerous developments in the field of medical diagnosis, especially for Positron Emission Tomography (PET). Developing new methodologies for the synthesis of biological tracers by a last-step 11C labeling, our team has been recently able to take advantage of the great functional tolerance of palladium-catalyzed carbonylation to achieve this goal. A new synthetic strategy involving preformed palladium complexes is described in this manuscript. Their anchoring on a polystyrene resin allowed subsequently to facilitate the carbonylation process by simplifying the purification. New palladium complexes have also been investigated for their potential photoredox applications. Finally, new coupling strategies implying gold (III) intermediates and photoredox catalysis being a very attractive subject, new gold complexes have been synthetized in order to investigate the reaction mechanisms that could operate. Possibilities of asymmetric induction in the synthesis of atropoisomeric biaryl compounds were also studied. Complexes supportés Carbonylation Carbone-11 Catalyse à l'or Photorédox Catalyse asymétrique Ligands rédox Supported complexes Carbonylation Carbon-11 Gold catalysis Photoredox Asymmetric catalysis Redox-active ligands
28	Synthèse et caractérisation de complexes de coordination contenant des ligands redox-actifs / Synthesis and characterization of complexes containing redox active ligands Kochem, Amélie 26 October 2012 (has links) Les radicaux organiques tiennent une place de choix dans de nombreux domaines et il est établi que ceux-ci peuvent exister coordinés à des centres métalliques dans les métalloenzymes. La Galactose Oxydase par exemple contient une entité cuivre(II)-radical phénoxyle indispensable à sa réactivité pour l'oxydation aérobie d'alcools en aldéhydes. Ces travaux de thèse ont consisté en l'élaboration de complexes de métaux de transitions (cuivre, nickel, cobalt) à partir de ligands noninnocents. Les caractérisations des espèces sous divers degrés d'oxydation ont été réalisées par différentes techniques complémentaires d'analyse (l'électrochimie, la RPE, l'UV-visible-proche-IR, la resonance raman ainsi que la diffraction des rayons X) combinées à des études de chimie théorique. Nous avons synthétisé des complexes Ni(II)-salen symétriques et dissymétriques et montré que l'espèce oxydée radicalaire pouvait acquérir un caractère localisé (composé de classe II) ou délocalisé (composé de classe III selon Robin-Day) en fonction des substituants phénoliques. Dans des complexes Cu(II)-salophen nous avons mis en évidence une activité redox centrée sur le pont, conduisant à des espèces Cu(II)-radicaux π diaminobenzène. Dans le cas des complexes de cobalt, les orbitales redox actives du métal et du ligand sont si proches en énergie que l'espèce oxydée est un hybride de résonance entre les formes Co(III)-phénolate et Co(II)-phénoxyle. Nous avons évalué l'influence du remplacement des oxygènes du salen par des azotes sur la structure électronique des espèces oxydées. Enfin, des complexes ont été mis au point à partir d'un ligand bis(phénol)-dipyrrine et les espèces oxydées radicalaires ont été caractérisées structuralement. Elles ont un caractère mixte porphyrinyle-phénoxyle jamais mis en évidence au préalable. / Organic radicals play key roles in various fields and it is established that they could coordinate metal centers in metalloenzymes. For example, Galactose Oxydase exhibits a copper-phenoxyl entity, essential for its reactivity (aerobic oxidation of alcohols to aldehydes). This thesis is focused on the design of transition metal complexes (copper, nickel, cobalt) from non innocent ligands. The characterization of species at various oxidation states has been performed by complementary analytical techniques (electrochemistry, EPR, UV-vis-NIR, raman resonance, X-ray crystallography) and theoretical chemistry. Several Ni-salen complexes were synthetized (symmetrical or not) and the resulting oxidized species could be either localized (class II compound) or delocalized (class III compound) radicals depending on the phenolic substituents. In Cu(II)-salophen complexes we successfully shed light on a bridge-centered redox activity, leading to Cu(II)-diaminobenzene π radical species. In the case of cobalt, both metal and ligand redox active orbitals are isoenergetic and the oxidized species is a resonance hybrid between the Co(III)-phenolate and the Co(II)-phenoxyl forms. We evaluated the influence of the replacement of the salen oxygen atoms by nitrogen ones on the electronic structure of the resulting oxidized species. Finally, original complexes were synthesized from a bis(phénol)-dipyrrine ligand and the radical oxidized species were structurally characterized. They exhibit a unprecedented mixed porphyrinyl-phenoxyl character. Biomimétisme Complexes Cuivre Nickel Cobalt Ligands redox actifs Radicaux Phénoxyles Anilinyles Thiyle Biomimetism Complexes Copper Nickel Cobalt Redox active ligands Radicals Phenoxyls Anilinyls Thiyl Electrochemistry
29	Redox Active Ligands To Facilitate Reactivity From Redox Restricted Metals Matthew C Hewitt (11197530) 29 July 2021 (has links) The synthesis of metal-redox active ligand complexes is described, along with reactivity studies aimed at facilitating novel C-N bond forming reactions. A copper bis(iminosemiquinone) structure is characterized, analyzed and its reduction series are characterized and the reactivity of the Cu(II) bis(amidophenolate) analog is investigated with tosyl azide. The identification of the major reaction product and its characterization is detailed, with reaction sensitivities and heavily distorted x-ray diffraction single crystal structure generating a complex data set. The characterization of the isolated product is ongoing, with EPR studies aimed at identifying the radical nature of the complex. Unusual solvent effects and solubility issues have been noted with these initial EPR studies and more data is necessary before analysis can be properly attempted. An ytterbium bis(amidophenolate) complex was synthesized and its reactivity studied with aryl azides. Initial reactivities generate the first documented lanthanide tetrazenes in-lieu of the targeted ytterbium imido. Reactivities and characterization of these complexes support a stable, heavily ionic tetrazene-metal complex with no observed redox nature, UV light sensitivities, or imido azide-tetrazene equilibrium observed in various tetrazene transition metal complexes. Synthesis of a sterically blocked ytterbium imido was attempted, utilizing DMAP. Initial isolation was achieved with characterization and reactivity studies supporting the imido nature of the complex. The weak coordinating of the DMAP provided instability that proved in opposition to crystallization, however, so the imido could not be confirmed. Initial reactions using alternative steric hinderance from triphenylphosphine oxide and pyridine N-oxide prove promising to increasing the stability of the presumed ytterbium imido. Organic synthesis was performed generating a potential antibacterial agent. The synthesis of cyclopropenes was initiated as antagonists for ETR proteins in fruits and plants. The intermediates proved highly sensitive to harsh chemical conditions, which was overcome utilizing a tin-mediated Barbier allylation. The cyclopropene alcohol synthon was synthesized, though protecting group optimization is necessary. f-Block Chemistry Transition Metal Chemistry Organic Chemical Synthesis Organometallic Chemistry amidophenolate complexes Copper Complexes Redox active ligands Ytterbium Complexes agrochemical adjuvants nitrene transfer reaction Copper Hydride Reductions
30	ADVANCING PRACTICAL NONAQUEOUS REDOX FLOW BATTERIES: A COMPREHENSIVE STUDY ON ORGANIC REDOX-ACTIVE MATERIALS Zhiguang Li (17015934) 25 September 2023 (has links) <p dir="ltr">As the demand for energy rises and the threat of climate change looms, the need for clean, reliable, and affordable energy solutions like renewable energies has been more crucial. Energy storage systems (ESSs) are indispensable in addressing the intermittent nature of renewable energies and optimizing grid efficiency. Redox flow batteries (RFBs), thanks to their scalability, independent energy and power, swift response time, and minimal environmental impact, are a particularly promising ESS technology for long-duration storage applications. Despite the technological maturity of aqueous RFBs, nonaqueous organic RFBs (NAORFBs) are a prospective solution due to their wider operational voltage, potentially higher energy density, and larger pool of redox-active materials. However, the current state-of-the-art NAORFBs face challenges due to the lack of suitable organic redox-active materials (ORMs).</p><p dir="ltr">Despite the development of new materials, how their variables influence the total system cost of RFBs remains an unsolved challenge. With this regard, we established a techno-economic (TE) model to calculate the capital cost of nonaqueous hybrid RFBs (NAHRFBs). Prior to this work, NAHRFBs, which employs lithium metal as the anode, were regarded as an RFB system with the highest energy density. However, the correlation between their features and the system cost remained unclear, leaving a research gap for new ORMs. In our model, we selected a state-of-the-art NAHRFB system where 2,2,6,6-tetramethylpiperidine-1-oxyl (TEMPO) serves as the catholyte and lithium metal functions as the anode. Thereafter, sensitivity analyses identified several key factors that determine the system cost, including operational current density, area-specific resistance, cell voltage, electrolyte composition, and both the price and equivalent molecular weight of the ORM. To enhance the cost-competitiveness of current NAHRFBs, it is advised to increase the current density by 10 times and modulate the ORM-related characteristics. The virtually optimized condition manifests that the system cost of NAHRFB can meet the long-term cost target set by the U. S. Department of Energy.</p><p dir="ltr">Informed by the TE model, we discovered that elevating the oxidation potential of catholyte ORMs is instrumental in reducing the system cost of RFBs. To explore this possibility, we incorporated fluorine atoms, a potent electron-withdrawing group (EWG), into a dimethoxybenzene (DMB) derivative, yielding a new ORM (ANL-C46) with an oxidation potential enhanced by ~0.41 V. Surprisingly, ANL-C46 demonstrated superior kinetic and electrochemical stability compared to its parent molecule, as indicated by electron paramagnetic resonance (EPR) study and bulk electrolysis. In particular, the cycling performance of ANL-46 during the bulk electrolysis outperformed most reported high-potential (> 1 V vs. Ag/Ag<sup>+</sup>) ORMs. Density functional theory (DFT) calculations reveals that the introduced fluorine substituents suppress the typical side reaction pathways of the DMB series. These findings offer valuable insights into molecular engineering strategies that concurrently improve multiple desired ORM properties.</p><p dir="ltr">The stability of ORMs is critical for ensuring the extended lifetime of RFBs. We conducted a systematic exploration of the conjugation effect, which potentially stabilizes the ORMs by facilitating a more homogeneous distribution of delocalized charges. This was applied to tailor the electrochemical and physical properties of several DMB derivatives with varying aromatic ring counts. As we extended the aromatic core from 1,4-dimethoxybenzene (1,4-DMB) to 1,4-dimethoxynaphthalene (1,4-DMN), we noted a decrease in oxidation potential, enhanced kinetic stability, and an extended cycling life. However, further extending the aromatic core to 2-ethyl-9,10-dimethyanthracene (EDMA) results in rapid dealkylation of the radical cation due to increased strain in the methoxy substituents. Additionally, 1,4-DMN shows cross-reactions between radical cations, likely via disproportionation. This study demonstrates that extending the π-conjugation changes reactivity in multiple ways. Therefore, attempts to lower oxidation potential and improve ORMs stability through π-conjugation should be pursued with caution.</p> redox flow batteries (RFB) nonaqueous electrolyte system organic redox active materials Techno-economics analysis

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