Syntheses of novel bis(alkylimino)acenaphthene (BIAN) and tetrakis(arylimino)pyracene (TIP) ligands and studies of their redox chemistry

Vasudevan, Kalyan Vikram

06 August 2010

The evolution of the present work began with the syntheses of novel bis(alkylimino)acenaphthene (BIAN) ligands. At the outset of this research, despite the presence of dozens of aryl-BIAN ligands in the literature, there were as of yet no reported BIAN ligands bearing alkyl substituents. Given the nearly ubiquitous use of transition metal complexes of alkyl diazabutadiene (DAB) ligands for e.g. catalysis and as ligands for carbene chemistry, interest was generated in developing this emerging field of synthetic chemistry. Initial studies focused on the synthesis of alkyl-BIAN ligands since the traditional synthetic approaches that had been developed for aryl-BIAN ligands were unsuccessful for the alkyl analogues. As an alternate synthetic route, it was decided to employ amino- and imino-alane transfer reagents which had previously proved successful for the conversion of C=O into C=N-R functionalities. While this transfer route had proved successful to synthesize moderate yields of highly fluorinated DAB ligands, it was unknown how or whether this methodology would apply in the case of alkylated BIAN systems. Over the past decade, there has been a surge of interest regarding lanthanide complexes that are capable of undergoing spontaneous electron transfer processes. There are several reports in the literature that describe the ability of Ln(II) ions to undergo spontaneous oxidation, thereby causing one-electron reduction of the coordinated ligand and generally resulting in the corresponding Ln(III) complex. The present work focused on an enhanced understanding of the electronic communication between the lanthanide and the attached ligand. Particular emphasis was placed on defining the resulting oxidation states and the manner in which delocalized electrons of the radical anion species travel over a conjugated system. This fundamental information was gleaned from single-crystal X-ray diffraction studies and magnetic moment measurements that were obtained using the Evans method. Additional insights stemmed from the use of more classical techniques such as IR and NMR spectroscopy. In favorable cases, the presence or absence of spectral peaks can permit assignment of the lanthanide oxidation state. Accordingly, the research plan was to synthesize a series of BIAN-supported decamethyllanthanocene complexes with the goal of learning how to control the spontaneous charge transfer that had been reported in the literature. A longer term goal was to develop a bifunctional ligand of the BIAN type that was capable of accommodating two lanthanide or main group element moieties. Systems with tunable electronic interactions between lanthanide or main group elements are of interest because they offer the prospect of extended delocalization of electron density. Systems of this type have potential applications as e.g. molecular wires and single-molecule magnets. Indeed, such systems have been investigated by using bis(bipyridyl) and bis(terpyridyl) ligands to support two redox-active moieties. However, in the present work, it was recognized that a bifunctional BIAN-type ligand might be of considerable interest as the supporting structure for studying the communication between lanthanide or main group element moieties. A synthesis of variously substituted tetrakis(imino)pyracene (TIP) ligands was therefore undertaken. The flat, rigid nature of the TIP ligands rendered them ideal scaffolds for studying the redox behavior and electronic communication between lanthanide or main group element centers. The new TIP ligand class also proved to be useful for the assembly of the first example of a metallopolymer based on a BIAN-type ligand. / text

Charge transfer

Redox-active ligands

Lanthanides

Main group

BIAN

TIP

Indigo mono- and diimine ligands as proton and electron reservoirs

Hofsommer, Dillon T.

07 August 2019

Indigo N,N’-diarylimine (Nindigo) and indigo N-arylimine (Mindigo) are redox-active ligands which exhibit near-infrared absorption and can accommodate up to five ligand charge states. This dissertation explores the coordination chemistry of these ligands to further understand the role that metal-ligand combinations play on ligand-centered properties, which include electrochemical potentials, UV-Vis-NIR absorption, pKa values, hydricities, and NH bond strengths at different ligand charge states. A series of cis-Nindigo palladium complexes containing acetylacetonate (acac) and hexafluoroacetylacetonate (hfac) ligands were synthesized. The acac complexes were easier to oxidize by 0.11 to 0.16 V and absorbed at lower wavelengths compared to their hfac analogues. Complexes using indigo bis(4-methylphenylimine) were more easily reduced than complexes of indigo bis(2,6-dimethylphenylimine). Cis- and trans-Mindigo complexes of palladium acac and hfac were synthesized as the first coordination complexes of Mindigo. Trans-Mindigo complexes were more difficult to reduce by 0.33 to 0.37 V and absorbed at lower wavelengths than their cis-Mindigo counterparts. Cis-Mindigo complexes were easier to reduce and harder to oxidize than the corresponding cis-Nindigo complexes. The NH bond strengths of cis-Nindigo complexes containing Pd(acac) and Ru(bipy)2 (bipy = 2,2’-bipyridyl) fragments were determined through a potential-pKa diagram in tetrahydrofuran and acetonitrile, respectively. The NH bond strength and hydricity values of the Pd(acac) complex were comparable to the values of diaryl amines. The NH bond strength and hydricity of the Ru(bipy)2 complex were substantially smaller due to the lower oxidation potentials of this complex. In both cases, the ligand’s NH bond strengths were not affected greatly by the ligand’s charge state. Ru(acac)2 complexes of neutral, aprotic cis-Nindigo and cis-Mindigo ligands were synthesized. The Nindigo/Mindigo ligand could be protonated, and the resulting complexes demonstrated substantial temperature dependence of some of their 1H NMR chemical shifts. The NH bond strengths and hydricities of the Ru(acac)2 complexes were determined using cyclic voltammetry and pKa measurements. The NH bond strengths and hydricities of these complexes are substantially smaller than the Pd(acac) and Ru(bipy)2 complexes. Collectively, these results show that Nindigo and Mindigo can act as both a proton and electron reservoirs, and the thermodynamics of proton and electron transfer can be tuned through the choice of metal and ligand combinations. / Graduate / 2020-07-17

Redox Active Ligands

Proton-coupled electron transfer

Dyes

Coordination Chemistry

Ruthenium

Palladium

Late First-Row Transition Metals in Weak Ligand Fields - Correlating High-Spin Electronic Structure and Reactivity

Sazama, Graham Thomas

16 September 2013

High spin has been shown to be necessary for optimal reactivity of transition metal complexes toward the activation and functionalization of C-H bonds. This thesis presents our examination of the weak-field, tripodal, trianionic tris(pyrrolyl)ethane (tpe) ligand and its complexes. Outer-sphere oxidation of the manganese, iron, cobalt, nickel and zinc complexes of tpe were performed by electrochemical and chemical methods. Electrochemical oxidation occurred at the same potential for each species, suggesting a ligand-based oxidation. The reaction product of chemical oxidation of iron showed oxidation of a pyrrole unit followed by H-atom abstraction to form a dichelated species. Density functional theory calculations confirm these results, and in silico oxidation of the complexes is entirely ligand-based. These results establish that tpe complexes are oxidized at the pyrrolide subunits in outersphere electron transfers, and elucidate minimal metal-ligand electronic communication. The more reactive \([(tpe)Fe(THF)]^−\) anion exhibits rapid binding of three equivalents of tert-butyl isonitrile, while reaction with excess carbon monoxide induces ligand fragmentation to form a species wherein two molecules of carbon monoxide have been reductively coupled. A mechanism based on the observed isonitrile species is proposed. The use of inner-sphere oxidant reagents allows for several stable iron (III) complexes of tpe to be isolated and characterized. Alkyl peroxides and alkyl disulfides, organic azides, and diphenyldiazomethane are all shown to oxidize iron by a single electron. Reaction with organic azides results in the formation of iron (III) amide species, likely as a result of Hatom abstraction. The weak-field of tpe creates a high propensity for forming high-spin iron (III) complexes, to the extent that diphenyldiazoalkane acts as a redox-active ligand and provides a one-electron reservoir to reveal a high-spin \(Fe^{3+}\). Spectroscopic and computational studies were undertaken to rigorously assign the physical oxidation state of iron in all cases. Given the outer-sphere redox liability of the tpe ligand, and the capability for inner-sphere oxidation local to iron, tpe complexes of iron represent a new class of metal-ligand redox activity, wherein the metal and ligand form two separate redox reservoirs, accessible via different mechanisms. / Chemistry and Chemical Biology

Inorganic chemistry

iron

oxidation

pyrrole

redox

redox-active ligands

tris(pyrrolyl)ethane

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

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

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

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

Redox Active Ligands To Facilitate Reactivity From Redox Restricted Metals

Matthew C Hewitt (11197530)

29 July 2021

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

Exploration de nouvelles stratégies catalytiques pour le développement de méthodes d'oxydation / oxygénation aérobies / Exploration of new catalytic strategies for the development of O2-promoted oxidizing/oxygenating methodologies

Moutet, Jules

06 December 2017

Ce travail est consacré à la conception, à la synthèse et à l’étude de catalyseurs d’oxydation à base de métaux 3d en association avec des ligands non-innocents. Tout d’abord, le développement de complexes dérivés de deux ligands rédox-actifs tétra-azotés originaux (motifs o-phénylènediamine, aniline et dipyrrine) a été étudié. Plusieurs espèces dans différents états d’oxydation ont été préparées. L’élucidation de leurs structures électroniques a été réalisée par des techniques complémentaires (diffraction des rayons X, électrochimie, spectroscopies UV-Vis-NIR, EPR et Mössbauer). Un complexe de fer biradicalaire basé sur le ligand bis(2-aminophényl)-o-phénylènediamine a été synthétisé. Parallèlement, une architecture innovante bis(2-aminophényl)dipyrrine a été développée. En réaction avec du nickel, du cuivre et du cobalt, elle a conduit à trois complexes isostructuraux présentant un caractère radicalaire anilinyle-dipyrrinyle jamais mis en évidence auparavant. La complexation de cette dipyrrine au manganèse a formé un singulier complexe dinucléaire radicalaire avec une valence mixte inhabituellement localisée sur le ligand.Dans un second temps, les complexes de fer, de cuivre et de manganèse ont été évalués dans des applications d’oxydation. L’étude de la réactivité du biradicalaire de fer a entraîné l’observation d’une espèce à haute valence en spectroscopie Mössbauer. D’autre part, le complexe de cuivre a montré une activité en oxydation d’un alcool. Enfin, une activité en catalyse d’oxygénation aérobie a été identifiée avec le complexe dinucléaire radicalaire de manganèse. / This work is devoted to the design, the synthesis and the study of oxidation catalysts, based on 3d metals and non-innocent ligands. First, the development of complexes derived from two unprecedented tetra-nitrogenated redox-active ligands (o-phenylenediamine, aniline and dipyrrin motifs) has been investigated. A number of species at various oxidation states has been prepared. The elucidation of their electronic structures was performed by complementary techniques (X-Ray diffraction, electrochemistry, UV-Vis-NIR, EPR and Mössbauer spectroscopy). A biradical iron complex based on the bis(2-aminophenyl)-o-phenylenediamine ligand was synthesized. In parallel, an innovative bis(2-aminophenyl)dipyrrin architecture was developed. Its reactions with nickel, copper and cobalt led to three isostructural complexes, showing an unprecedented anilinyl-dipyrrinyl radical character. The complexation of the dipyrrin to manganese afforded a unique dinuclear radical complex with a rare ligand-based mixed valence.In a second phase, iron, copper and manganese complexes were assessed in oxidation applications. The reactivity study of the biradical iron resulted in the observation of a high-valent species thanks to Mössbauer spectroscopy. On the other hand, the copper complex has shown an activity in the oxidation of an alcohol. Finally, a catalytic aerobic activity in oxygenation catalysis was identified with the dinuclear manganese radical complex.

Ligands rédox-Actifs

Radicaux azotés

Métaux abondants (Ni; Cu; Co; Fe; Mn)

Anilines

O-Phénylènediamines

Réactivité avec le dioxygène

Redox-Active ligands

N-Centered radicals

Anilines

O-Phenylenediamines

Reactivity with dioxygen

540