Global ETD Search

61	New transition metal complexes with functional N-heterocyclic carbene ligands for molecular activation / Nouveaux complexes des métaux de transition à ligands carbéniques fonctionnels pour l'activation moléculaire Simler, Thomas 10 March 2016 (has links) Le sujet de cette thèse porte sur l’étude de ligands hybrides incorporant un donneur carbène N-hétérocyclique (NHC). Les ligands phosphine-NHC construits sur le motif m-phénylène ont conduit à des complexes di- ou tétranucléaires d’Ag, Cu, Au et Ir, et à des complexes bimétalliques Ag/Cu et Ag/Ir par transmétallation sélective du site NHC. Dans le cas des ligands phosphino-picoline-NHC (PNC), la transmétallation des sels de Li ou K correspondants a permis d’isoler des complexes « pinceurs » dé-aromatisés du Cr, Fe et Co. La déprotonation du ligand bis(phosphinométhyl)pyridine (PNP) a été examinée, et les ligands dé-aromatisés mono- et bis-anioniques correspondants ont été utilisés dans des réactions de transmétallation vers le Cr(II) et Zr(IV). Différents modes de coordination des ligands dé-aromatisés, notamment une métallation de la position alpha-CHP, ont été observés. La substitution de la phosphine dans PNC par une fonction imine conduit à un ligand hybride « rédox non-innocent ». / The purpose of this work is the synthesis and study of hybrid and potentially “pincer” ligands featuring an N-heterocyclic carbene (NHC) donor. The phosphine-NHC ligands based on the m-phenylene framework led to di- or tetranuclear Ag, Cu, Au and Ir complexes, and to bimetallic Ag/Cu and Ag/Ir complexes by selective transmetallation of the NHC. With the phosphino-picoline-NHC (PNC) ligands, transmetallation from the corresponding Li or K salts led to dearomatised Cr, Fe and Co “pincer” complexes. Deprotonation of the bis(phosphinomethyl)pyridine (PNP) ligand was also examined. The corresponding dearomatised mono- and bis-anionic ligands were isolated as Li or K salts and further used in transmetallation reactions towards Cr(II) and Zr(IV). Different coordination modes of the dearomatised ligands, including side-arm metallation, were observed. Substitution of the phosphine group in PNC by an imine donor led to a hybrid and “redox non-innocent” ligand. Carbènes N-hétérocycliques (NHC) Complexes bimétalliques Ligands pinceurs non-symétriques Transmétallation Ligands dé-aromatisés N-heterocyclic carbenes (NHC) Bimetallic complexes Non-symmetric pincer ligands Transmetallation Dearomatised ligands 546.3
62	From early to late transition metal complexes: syntheses, structures and electrochemical properties Köcher, Stefan 01 December 2008 (has links) Die vorliegende Arbeit befasst sich mit der Synthese, dem Reaktionsverhalten, den Festkörperstukturen und den elektronischen Eigenschaften von neuartigen Übergansmetall-komplexen der Gruppen 4, 8 und 10 des Peridoensystems der Elemente. Die Arbeit befasst sich unter anderem mit der Darstellung von Alkyloxy- und Aryloxy-substituierten Titanocenverbindungen des Typs [Ti](Cl)(OR) {[Ti] = (C5H5SiMe3)2Ti; R = organischer Rest). Mittels cyclovoltammetrischer Experimente und anhand von Festkörpestrukturen wird der elektronische Einfluss der organischen Reste auf das Metallzentrum untersucht. Weiterhin befasst sich die Arbeit mit der Synthese von in para-Position substituierten NCN-Pincerverbindungen. Durch die Wahl des Substituenten in para-Postition sowie des Übergangsmetalls der Gruppe 10 des Periodensystems der Elemente ist es möglich, verschiedenartig gerichtete polymere Strukturen zu bilden. Ein weiterer Schwerpunkt der vorliegenden Arbeit liegt in der Synthese und Untersuchung der elektronischen Eigenschaften von NCN-Pincer-substituierten Ferrocenen. Der Einfluss der NCN-Pincer auf die Elektronendichte des Ferrocens wird bestimmt sowie die Eignung derartiger Systeme als elektrochemische Sensoren zur molekularen Erkennung von Schwefeldioxid wird untersucht. info:eu-repo/classification/ddc/540 ddc:540 Cyclovoltammetrie Ferrocen Ferrocenderivate Metallorganische Verbindungen Nitrile Oxime Polymerkomplexe Titanocenderivate Biferrocen Koordinationspolymer NCN-Pincer Palladium(II) Platin(II) heterometallisch
63	Synthesis, characterization, and photophysics of symmetric and unsymmetric -NHC pincer platinum halide complexes and derivatives Zhang, Min 14 December 2018 (has links) A series of 24 new photoluminescent symmetric and unsymmetric -NHC pincer Pt complexes was synthesized and characterized, including collection of their 195Pt NMR chemical shifts. In total 18 new X-ray crystal structures, and photophysical studies of these photoluminescent -NHC pincer Pt complexes are reported. -NHC pincer Pt complexes were synthesized and characterized using new -NHC pincer based proligands [(RChetChetCRH3)X2, X = Cl, Br, or BPh4, where het represents imidazolyl, benzimidazolyl, and 1,2,4-triazolyl moieties; R = n-butyl, 3,3-dimethylbutyl, n-hexyl] as starting materials. A new method to synthesize Pt-Cl complexes to prevent halogen mixing was developed using tetraphenylborate salts as proligands. -NHC pincer complexes Pt(II) were oxidized to Pt(IV) complexes by reaction with Br2, I2, or iodobenzene dichloride. Photophysical studies showed emission of blue to red-orange color range for the Pt(II) complexes when irradiated with long wavelength UV light (360 nm). No visible emission for Pt(IV) complexes was observed upon irradiation at 360 nm. The tunable photoluminescence of the synthesized -NHC pincer Pt(II) complexes can be used as the materials for OLEDs. Parameters and scales that provide understanding of steric and electronic effects are essential to predicting properties, and, therefore, to systematically designing new ligands. Meridional tridentate pincer ligands are neither conveniently nor accurately described by existing options. A scale has been developed based on 195Pt NMR chemical shift that is reflective of the total donor ability of a multi-dentate ligand in a square planar complex and that does not suffer from cis/trans stereochemical issues. This scale, Platinum Electronic Parameter (PtEP) and defined as PtEP = -(195Pt NMR shift) in CDCl3 revealed significant deviations of -NHC pincer ligands, PCP and POCOP donor abilities from predicted extrapolations using existing TEP parameters. This initial data set demonstrates the applicability and broad potential of the PtEP scale. N-heterocyclic carbene Tetraphenylborate salts -NHC pincer ligand photoluminescent Pt(II) complexes PtEP ligand donor ability 195Pt NMR spectroscopy Pt(IV) complexes
64	Group 3 Metal Complexes of Rigid Neutral and Monoanionic Pincer Ligands Vasanthakumar, Aathith January 2020 (has links) The synthesis of a rigid 4,5-bis(triphenylphosphinimino)-2,7-di-tert-butyl-9,9-dimethylxanthene (Ph3PN)2XT (1) ligand is outlined, along with a modified synthesis for previously reported 1,8-bis(triphenylphosphinimino)naphthalene (Ph3PN)2NAP (3). Reaction of neutral (Ph3PN)2XT with [Y(CH2SiMe3)3(THF)2] resulted in double cyclometallation, yielding the base-free monoalkyl complex, [({Ph2(C6H4)PN}2XT)Y(CH2SiMe3)] (2). Layering a concentrated THF solution of 2 with hexanes at −28 °C afforded THF-coordinated [({Ph2(C6H4)PN}2XT) Y(CH2SiMe3)(THF)]·2THF (2-THF·2THF), with a distorted pentagonal bipyramidal geometry and approximately meridional coordination of the pentadentate {Ph2(C6H4)PN}2XT dianion. Similarly, (Ph3PN)2NAP reacted with [Y(CH2SiMe3)3(THF)2] to afford a THF-coordinated monoalkyl complex, [{(Ph2(C6H4)PN)2NAP}Y(CH2SiMe3)(THF)] (4-THF). Layering a DME solution of 4-THF with hexanes at −28 °C afforded X-ray quality crystals of [{(Ph2(C6H4)PN)2NAP}Y(CH2SiMe3)(κ2-DME)]·hexane (4-DME·hexane), with a highly distorted pentagonal bipyramidal geometry and a facial coordination mode of the tetradentate {Ph2(C6H4)PN}2NAP dianion The synthesis of a rigid 4,5-bis(1,3-diisopropylimidazol-2-imine)-2,7,9,9-tetramethylacridan H(AII2) ligand (5) was achieved via a Buchwald-Hartwig cross-coupling reaction. Reaction of the proligand H(AII2) with [M(CH2SiMe3)3(THF)2] (M = Y(6), Sc(8)) yielded the base free dialkyl complexes [(AII2)Y(CH2SiMe3)2] (6) and [(AII2)Sc(CH2SiMe3)2] (8). The reaction of 6 with one equivalent of [CPh3][B(C6F5)4] yielded [(AII2)Y(CH2SiMe3)][B(C6F5)4] (7) in-situ. Complex 7 proved to be a potent intramolecular hydroamination catalyst for a variety of aminoalkane substrates. The attempted synthesis of 4,5-bis(1,3-diisopropylimidazol-2-imine)-2,7-di-tert-butyl-9,9-dimethylxanthene (XII2) via the Staudinger reaction resulted in the isolation of the triazene intermediate 4,5-bis(1,3-diisopropylimidazol-2-yliedene{triazene})-2,7-di-tert-butyl-9,9-dimethylxanthene XIA2 (9). Reaction of XIA2 with one equivalent of [Y(CH2SiMe3)3(THF)2] led to the isolation of [(XIA2)Y(CH2SiMe3)3] (10). Synthesis of XII2 (11) was achieved via a Buchwald-Hartwig cross-coupling reaction. Reaction of XII2 with one equivalent of YCl3(THF)3.5 resulted in the isolation of [(XII2)YCl3] (12). In contrast, the reaction of XII2 with one equivalent of [Y(CH2SiMe3)3(THF)2] led to several unidentified products. Reaction of XII2 with 1 equivalent of [H(Et2O)2][B(C6F5)4] led to the isolation of the precursor [H(XII)2][B(C6F5)4] (13). The reaction of 13 with 1.1 equivalents of [M(CH2SiMe3)3(THF)2] (M = {Y(14), Sc(15)} led to the isolation of the monocationic [(XII)2M(CH2SiMe3)2][B(C6F5)4] complexes. The reaction of [(XII)2Sc(CH2SiMe3)2][B(C6F5)4] with 1.1 equivalents of B(C6F5)3 led to the abstraction of a methyl anion from the silicon center, with concomitant migration of the remaining alkyl group to the positively charged silicon, forming a new CH2SiMe2CH2SiMe3 alkyl group. This process is accompanied by MeB(C6F5)3 anion formation, forming a contact ion pair to afford the dicationic species [(XII)2Sc(CH2SiMe3)][MeB(C6F5)3][B(C6F5)4] 16. In contrast, the reaction of 15 with 1.3 equivalents of [CPh3][B(C6F5)4] in the presence of 5 equivalents of toluene resulted in the synthesis of [(XII)2Sc(CH2SiMe3)(ɳx-toluene)][B(C6F5)4]2 17 in-situ. Complex 17 is a highly potent ethylene polymerization catalyst with an activity of 868 kg/mol·atm·h. The reaction of 15 with [HNMe2Ph][B(C6F5)4] led to the cyclometallation of the resulting NMe2Ph byproduct to yield [(XII2)Sc(C6H4NMe2)][B(C6F5)4]2 (18) in-situ. The synthesis of a rigid, asymmetric 4-(1,3-diisopropylimidazol-2-imine)-5-(2,6-diisopropylanilido)- 2,7-di-tert-butyl-9,9-dimethylxanthene XAI (19) ligand was achieved by a two step Buchwald-Hartwig cross-coupling reaction with initial cross coupling of 1,3-diisopropylimidazol-2-imine followed by the cross-coupling of 2,6-diisoproylaniline. The reaction of XAI with 1.1 equivalents of [Y(CH2SiMe3)3(THF)2] yielded [(XAI)Y(CH2SiMe3)2] (20). Subsequent reaction of [(XAI)Y(CH2SiMe3)2] with 1 equivalent of [CPh3][B(C6F5)4] in the presence of 10 equivalents of toluene resulted in the synthesis of the toluene coordinated [(XAI)Y(CH2SiMe3)(ɳx-toluene)][B(C6F5)4] (21) complex. Similar to 7, complex 21 was highly active for intramolecular hydroamination of various substrates. / Dissertation / Doctor of Philosophy (PhD) / Cationic group 3 alkyl complexes are underreported in comparison to analogous group 4 complexes. The scarcity of these complexes can be attributed to their propensity to engage in undesirable reactions such as ligand redistribution and cyclometallation. To increase the thermal stability of such complexes, design features, such as carefully positioned steric bulk and ligand rigidity are beneficial. Additionally, such ligands must also have considerable donor ability, in order to stabilize inherently electron deficient cationic metal centers. This work details the synthesis of a variety of neutral and monoanionic ligands that incorporate the aforementioned design features, which were utilized in the successful synthesis of a variety of neutral, monocationic and extremely rare dicationic group 3 alkyl complexes. The cationic monoalkyl complex in this work proved to be a highly potent intramolecular hydroamination catalyst. Furthermore, a rare dicationic scandium complex was highly active for ethylene polymerization rare earth rare earth cations pincer ligands olefin polymerization intramolecular hydroamination imidazol-2-imine phosphinimine cyclometallation rare earth dications rare earth alkyl complexes
65	Complexes NCN de Ni(II) et Ni(III) : synthèse, caractérisation et rôle dans le mécanisme de couplage C-O, C-N et C-halogènes Cloutier, Jean-Philippe 09 1900 (has links) No description available. Complexes pinces Ni(II) Ni(III) Ni(IV) NCN Nickel Couplage C-O Couplage C-N Couplage C-halogènes Élimination réductrice Comproportionation Disproportionation Pincer complexes High-valent NCN pincer complexes Functionalization C-O coupling C-N coupling C-halogen coupling Reductive elimination C-H activation DFT
66	POCN-type Pincer Complexes of NiII and NiIII : synthesis, reactivities, catalytic activities and physical properties Spasyuk, Denis M. 08 1900 (has links) Cette thèse décrit la synthèse, la caractérisation, les réactivités, et les propriétés physiques de complexes divalents et trivalents de Ni formés à partir de nouveaux ligands «pincer» de type POCN. Les ligands POCN de type amine sont préparés d’une façon simple et efficace via l’amination réductrice de 3-hydroxybenzaldéhyde avec NaBH4 et plusieurs amines, suivie par la phosphination de l’amino alcool résultant pour installer la fonction phosphinite (OPR2); le ligand POCN de type imine 1,3-(i-Pr)2PC6H4C(H)=N(CH2Ph) est préparé de façon similaire en faisant usage de PhCH2NH2 en l’absence de NaBH4. La réaction de ces ligands «pincer» de type POCN avec NiBr2(CH3CN)x en présence d’une base résulte en un bon rendement de la cyclométalation du lien C-H situé en ortho aux fonctions amine et phosphinite. Il fut découvert que la base est essentielle pour la propreté et le haut rendement de la formation des complexes «pincer» désirés. Nous avons préparé des complexes «pincer» plan- carrés de type POCN, (POCNRR΄)NiBr, possédant des fonctions amines secondaires et tertiaires qui démontrent des réactivités différentes selon les substituants R et R΄. Par exemple, les complexes possédant des fonctions amines tertiaires ArCH2NR2 (NR2= NMe2, NEt2, and morpholinyl) démontrent des propriétés rédox intéressantes et pourraient être convertis en leurs analogues trivalents (POCNR2)NiBr2 lorsque réagis avec Br2 ou N-bromosuccinimide (NBS). Les complexes trivalents paramagnétiques à 17 électrons adoptent une géométrie de type plan-carré déformée, les atomes de Br occupant les positions axiale et équatoriale. Les analyses «DSC» et «TGA» des ces composés ont démontré qu’ils sont thermiquement stables jusqu’à ~170 °C; tandis que la spectroscopie d’absorption en solution a démontré qu’ils se décomposent thermiquement à beaucoup plus basse température pour regénérer les complexes divalents ne possédant qu’un seul Br; l’encombrement stérique des substitutants amines accélère cette route de décomposition de façon significative. Les analogues NMe2 et N(morpholinyl) de ces espèces de NiIII sont actifs pour catalyser la réaction d’addition de Kharasch, de CX4 à des oléfines telles que le styrène, tandis qu’il fut découvert que l’analogue le moins thermiquement stable (POCNEt2)Ni est complètement inerte pour catalyser cette réaction. Les complexes (POCNRH)NiBr possédant des fonctions amines secondaires permettent l’accès à des fonctions amines substituées de façon non symétrique via leur réaction avec des halogénures d’alkyle. Un autre avantage important de ces complexes réside dans la possibilité de déprotonation pour préparer des complexes POCN de type amide. De telles tentatives pour déprotoner les fonctions NRH nous ont permis de préparer des espèces dimériques possédant des ligands amides pontants. La nature dimérique des ces complexes [P,C,N,N-(2,6-(i-Pr)2PC6H3CH2NR)Ni]2 (R= PhCH2 et Ph) fut établie par des études de diffraction des rayons-X qui ont démontré différentes géométries pour les cœurs Ni2N2 selon le substituant N : l’analogue (PhCH2)N possède une orientation syn des substitutants benzyles et un arrangement ressemblant à celui du cyclobutane du Ni et des atomes d’azote, tandis que l’analogue PhN adopte un arrangement de type diamant quasi-planaire des atomes du Ni et des atomes d’azote et une orientation anti des substituants phényles. Les espèces dimériques ne se dissocient pas en présence d’alcools, mais elles promouvoient l’alcoolyse catalytique de l’acrylonitrile. De façon intéressante, les rendements de ces réactions sont plus élevés avec les alcools possédant des fonctions O-H plus acides, avec un nombre de «turnover» catalytique pouvant atteindre 2000 dans le cas de m-cresol. Nous croyons que ces réactions d’alcoolyse procèdent par activation hétérolytique de l’alcool par l’espèce dimérique via des liaisons hydrogènes avec une ou deux des fonctions amides du dimère. Les espèces dimériques de Ni (II) s’oxydent facilement électrochimiquement et par reaction avec NBS ou Br2. De façon surprenante, l’oxydation chimique mène à l’isolation de nouveaux produits monomériques dans lesquels le centre métallique et le ligand sont oxydés. Le mécanisme d’oxydation fut aussi investigué par RMN, «UV-vis-NIR», «DFT» et spectroélectrochimie. / This thesis describes the synthesis, characterization, reactivities, and physical properties of divalent and trivalent complexes of Nickel based on new POCN-type pincer ligands. The amino-type POCN ligands were prepared in a simple and efficient manner via reductive amination of 3-hydroxybenzaldehyde with NaBH4 and various amines, followed by phosphination of the resulting amino alcohol to install the phosphinite (OPR2) functionality. The imino-type POCN ligand 1,3-(i-Pr)2PC6H4C(H)=N(CH2Ph) was prepared similarly using PhCH2NH2 in the absence of NaBH4. Reaction of these POCN-type pincer ligands with NiBr2(CH3CN)x in the presence of a base results in the high yield cyclometalation of the C-H bond which is ortho to the amine and phosphinite functionalities. The base was found to be essential for a clean and high yield formation of the desired pincer complexes. We have thus prepared square planar POCN-type pincer complexes (POCNRR΄)NiBr featuring tertiary or secondary amine moieties that exhibit different reactivities as a function of amine substituents R and R΄. For instance, complexes bearing the tertiary amine moieties ArCH2NR2 (NR2= NMe2, NEt2, and morpholinyl) displayed interesting redox properties and could be converted into their trivalent analogues (POCNR2)NiBr2 when reacted with Br2 or N-bromosuccinimide (NBS). These 17-electron, paramagnetic trivalent complexes adopt a distorted square pyramidal geometry with Br atoms at axial and equatorial positions. DSC and TGA analyses of these compounds revealed them to be thermally stable up to ~170 °C; whereas absorption spectroscopy in solution showed that they undergo thermal decomposition at much lower temperatures to regenerate the monobromo divalent complexes; increased steric bulk of the amine substituents accelerate this decomposition pathway significantly. The NMe2 and N(morpholinyl) analogues of these NiIII species are active catalysts for the Kharasch addition of CX4 to olefins such as styrene, whereas the least thermally stable analogue (POCNEt2)Ni was found to be completely inert for this reaction. The complexes (POCNRH)NiBr featuring secondary amine moieties allow access to unsymmetrically substituted amine moieties via reaction with alkyl halides. Another important advantage of these complexes lies in the possibility of deprotonation to prepare amide-type POCN complexes. Such attempts at deprotonating the NRH moieties have allowed us to prepare dimeric species featuring bridging amido ligands. The dimeric nature of these complexes [P,C,N,N-(2,6-(i-Pr)2PC6H3CH2NR)Ni]2 (R= PhCH2 and Ph) was established through X-ray diffraction studies that showed different geometries for the Ni2N2 cores as a function of N-substituent: the (PhCH2)N analogue featured a syn orientation of the benzyl substituents and a cyclobutane-like arrangement of Ni and of the nitrogen atoms, whereas the PhN analogue adopted a nearly planar diamond-like arrangement of the Ni and of the nitrogen atoms and an anti orientation of the phenyl substituents. These dimeric species do not dissociate in the presence of alcohols, but they promote the catalytic alcoholysis of acrylonitrile. Interestingly, yields of these reactions are higher with alcohols possessing more acidic O-H moieties, with a catalytic turnover number reaching up to 2000 in the case of m-cresol. These alcoholysis reactions are believed to proceed through heterolytic activation of the alcohol by dimeric species via hydrogen bonding with one or two amido moieties in the dimer. The dimeric Ni (II) species were found to undergo facile oxidation both electrochemically and in reaction with NBS or Br2. Surprisingly, chemical oxidation led to isolation of new monomeric products in which both the metallic center and the ligand were oxidized. giving a trivalent species featuring an imine-type POCN ligand. Oxidation mechanism was investigated in detail by NMR, UV-vis-NIR, DFT and spectroelectrochemistry. Nickel (II) complexes POCN-type Nickel (III) complexes «pincer» X-ray diffraction thermogravimetric analysis olefin hydroalkoxylation differential scanning calorimetry spectroelectrochemistry C-H activation activation C-H RMN NMR voltampérométrie cyclique cyclic voltammetry hydroalkoxylation des oléfines «pincer» de type POCN diffraction des rayons-X
67	POCN-type Pincer Complexes of NiII and NiIII : synthesis, reactivities, catalytic activities and physical properties Spasyuk, Denis M. 08 1900 (has links) No description available. Nickel (II) complexes POCN-type Nickel (III) complexes «pincer» X-ray diffraction thermogravimetric analysis olefin hydroalkoxylation differential scanning calorimetry spectroelectrochemistry C-H activation activation C-H RMN NMR voltampérométrie cyclique cyclic voltammetry hydroalkoxylation des oléfines «pincer» de type POCN diffraction des rayons-X
68	Complexes pinceurs de type POCOP de Nickel (II) : synthèse, caractérisation, réactivité et applications catalytiques Salah, Abderrahmen 08 1900 (has links) Ce mémoire décrit la synthèse, la caractérisation spectroscopique et l’étude de la réactivité catalytique d’une nouvelle série de complexes pinceurs de Ni(II) formés à partir du ligand POCOPPh (P,C,P-2,6-{Ph2PO}2C6H4), très peu étudié dans le cas du nickel. Les études décrites dans ce mémoire examinent l’effet des substituants des phosphines sur les propriétés spectroscopiques et électrochimiques ainsi que les activités catalytiques. La synthèse du ligand a été améliorée par rapport à la procédure connue dans la littérature en diminuant le temps de réaction à 30 min et la température jusqu'à température ambiante. Les composés pinceur (P,C,P-2,6-{Ph2PO}2C6H3)NiX ont été obtenus avec des rendements variant entre 60% et 88%. Le premier complexe a été synthétisé en faisant réagir le précurseur NiBr2(NCCH3)x avec le ligand POCOPPh pour donner (POCOPPh)NiBr. Ce dernier réagit par la suite avec les sels d’argent et de potassium pour donner 4 nouveaux complexes soient : (POCOPPh)NiCN, (POCOPPh)NiOTf, (POCOPPh)NiOAc et (POCOPPh)NiONO2 (OTf = triflate et OAc = acetate). Vu la réactivité limitée du dérivé bromure, le dérivé (POCOPPh)NiOTf a été utilisé pour la préparation du composé (POCOPPh)NiCCPh. Le dérivé Ni-OTf a été utilisé également pour la synthèse des complexes (POCOPPh)NiR qui ont été détectés par RMN. Ces complexes (POCOPPh)NiR ont montré une stabilité trop faible et donnent des nouveaux complexes de type (POCOPPh)NiX en échangeant l’halogène avec le Mg ou de type (POCOPPh)NiOH en s’hydrolysant. Les espèces cationiques [(POCOPPh)NiNCR][OTf] (R= Me, CHCH2, CHCHMe, C(Me)CH2, NCCH2CH2N(Ph)H) ont été obtenues facilement et avec des bon rendements à partir du (POCOPPh)NiOTf. Tous les composés obtenus ont été caractérisés par la spectroscopie RMN (1H, 13C{1H}, 31P{1H}, 19F{1H}), la spectroscopie IR et la spectroscopie UV-vis. L’analyse élémentaire et l’analyse par la diffraction des rayons X, dont le but est de résoudre la structure à l’état solide, ont été utilisées pour la plupart des complexes. Des études de voltampérométrie cyclique ont été menées pour déterminer la densité électronique des centres métalliques et l’effet des phosphines sur cette propriété électrochimique. Dans le but de déterminer l’effet des substituants des phosphines sur l’activité catalytique des complexes, nous avons évalué les réactivités catalytiques des deux complexes (POCOPPh)NiOTf et (POCOPi-Pr)NiOTf dans la réaction d’hydroamination des oléfines activés et plus spécifiquement l’acrylonitrile. Après optimisation des conditions expérimentales, on a constaté que la réactivité des deux composés sont similaires mais une grande différence apparaît après l’ajout des additifs. En effet, le complexe (POCOPi-Pr)NiOTf donne une bonne activité catalytique en présence de la triéthylamine, tandis que cette activité diminue considérablement en présence d’eau, contrairement au complexe (POCOPPh)NiOTf qui est plus actif en présence d’eau. Dans le cas du complexe (POCOPPh)NiOTf, on a pu montrer que la base se coordonne au nickel dans le produit formé après la réaction d’hydroamination, ce qui diminue l’activité de ce complexe dans certains cas. Également on a exploré la réaction de l’addition du lien O-H sur l’acrylonitrile, et étonnamment le complexe (POCOPPh)NiOTf est beaucoup plus actif que son homologue (POCOPi-Pr)NiOTf dans le cas des alcools aromatiques. Par contre, les alcools aliphatiques restent un défi majeur pour ce genre de complexe. Le mécanisme de cette réaction qui a été proposé montre que l’alcoolyse passe par les deux intermédiaires (POCOPPh)NiOAr et [(POCOPPh)NiOAr][HOAr] mais l’isolation de ces intermédiaires observés par RMN semble être difficile. / This thesis describes the synthesis, spectroscopic characterization and the catalytic activities of a new family of pincer complexes of Ni (II) starting from the ligand POCOPPh (P,C,P-2,6-{Ph2PO}2C6H4) for which very few nickel complexes have been reported previsouly. We discuss the influence of P-substituents on the spectroscopic, electrochemical and catalytic activities of these complexes. The synthesis of POCOPPh has been improved comparatively to the procedure reported in the literature by reducing the reaction time to 30 minutes and the temperature to room temperature. The complex (P,C,P-2,6-{Ph2PO}2C6H3)NiBr was obtained with 88% yield by reacting the precursor NiBr2(NCCH3)x with POCOPPh . This complex was then reacted with various silver and potassium salts to give the following complexes (POCOPPh)NiCN, (POCOPPh)NiOTf, (POCOPPh)NiOAc and (POCOPPh)NiONO2 (OTf = triflate et OAc = acetate). The limited reactivity of the bromo derivative led us to use (POCOPPh)NiOTf for the preparation of some of the desired derivatives, such as (POCOPPh)NiCCPh. Attempts to prepare the desired alkyl derivatives (POCOPPh)NiR were not successful, but we were able to detect these derivatives using NMR. The thermal instability of (POCOPPh)NiR led to formation of new (POCOPPh)NiX complexes by halogen exchange with MgX2 or (POCOPPh)NiOH by hydrolysis. The cationic species [(POCOPPh)NiNCR][OTf] (R = Me, CHCH2, CHCHMe, C(Me)CH2, NCCH2CH2N(Ph)H) also were obtained easily from the (POCOPPh)NiOTf with good yields. All these complexes were characterized by elemental analysis, NMR spectroscopy (1H, 13C{1H} 31P{1H}, 19F{1H}), IR spectroscopy and UV-vis spectroscopy. For most complexes analysis by X-ray diffraction allowed us to establish their solid state structures. A few studies by cyclic voltammetry have been done to determine the electronic density of the metal center and the P-substituent influence on this characteristic. In order to investigate the effect of phosphine substituents on the catalytic activities of this type of complexes, catalytic studies were undertaken with the following two complexes (POCOPPh)NiOTf and (POCOPi-Pr)NiOTf in hydroamination of activated olefins specifically acrylonitrile. After optimization of experimental conditions, it was found that both complexes have similar activities but what makes a huge difference is the use of additives. Indeed, (POCOPi-Pr)NiOTf showed good catalytic activity in the presence of triethylamine as base but this activity decreased significantly in the presence of water. The opposite was observed with (POCOPPh)NiOTf complex: it was shown that triethylamine coordinates to the nickel center in this complex and hence reduces its activity in some cases. We Also explored other reactions such as the addition of the O-H bond in aromatic alcohols to acrylonitrile, and it was surprising that (POCOPPh)NiOTf is much more active than its homologous (POCOPi-Pr)-NiOTf. However aliphatic alcohols remain a major challenge for this kind of complex. Mechanistic studies suggest that this reaction passes through the following intermediates (POCOPPh)NiOAr and [(POCOPPh)NiOAr][HOAr]. These species were observed by NMR but not isolated. nickel complexe pinceur pincer complex POCOP POCOP-type catalyse catalysis hydroamination hydroalcoxylation hydroalkoxylation voltampérométrie cyclique cyclic voltammetry diffraction de rayons alcoholysis RMN X-ray diffraction GC-MS NMR
69	Complexes pinceurs de cobalt et de nickel : synthèse, caratérisation, réactivité Lefèvre, Xavier 08 1900 (has links) Plusieurs nouveaux complexes pinceurs de cobalt et de nickel ont été préparés avec le ligand pinceur de type POCOP : 2,6-(i-Pr2PO)2C6H4. Dans le cas du cobalt, une nouvelle voie de synthèse a été développée. Contrairement au cas du nickel, il s’agit ici de cobalt au degré d’oxydation +III. Les composés obtenus sont paramagnétiques. En outre, le dérivé bromé est instable à la lumière et se décompose en perdant un brome pour former le complexe pinceur de Co(II). La réactivité de ces complexes a été étudiée. Pour ce qui est du nickel, la catalyse de l’hydroamination a été élargie aux dérivés de l’acrylonitrile et aux amines aromatiques. En outre, la réaction d’hydroaryloxylation a été étudiée dans les mêmes conditions. Enfin, avec le 4-cyanostyrène et le cinnamonitrile, la formation d’amidines a été observée. Un complexe pinceur portant cette amidine a été isolé. Enfin, le cation réagit avec des anions fortement coordonnants tels le cyanure ou l’isocyanate. En outre, l’anion triflate peut être déplacé par l’eau, l’acrylonitrile et ses dérivés. Enfin, une réactivité particulière a été observée avec la morpholine, l’acétone et un mélange 1:1 aniline/triéthylamine. / A large variety of new POCOP pincer type complexes of cobalt and nickel have been prepared. All those complexes are based on the following POCOP pincer type ligand: 2,6-(i-Pr2PO)2C6H4 In the case of cobalt, a new synthetic pathway has been developped. Unlike nickel, complexes containing cobalt in the +III oxidation state are obtained, the mechanism of their formation remains unknown. These complexes are paramagnetic. The dibromo derivative is light-sensitive, decomposing by losing a bromine to form the Co(II) pincer complex. The reactivity of those complexes has been studied. Concerning nickel, the catalyzed hydroamination has been extended to the derivates of acrylonitrile, crotonitrile and methacrylonitrile and to aromatic amines. Moreover, hydroaryloxylation reaction has been studied under the same conditions. Finally, amidines formation was obtained with 4-cyanostyrene and with cinnamonitrile. A pincer complex bearing this amidine moiety has been isolated. The cationic complex reacts with strong coordinating anions like cyanide and isocyanate. Moreover, the triflate anion is displaced by water, acrylonitrile and acrylonitrile derivates. Finally, a particular reactivity has been observed with morpholine, acetone and a 1:1 mixture of aniline and triethylamine. Complexes pinceurs Pincer complexes Cobalt Cobalt Nickel Nickel Catalyse Catalysis Coordination Coordination Hydroamination Hydroamination Hydroalcoxylation Hydroalkoxylation Amidine Amidine Acrylonitrile Acrylonitrile Diffraction de rayons X X-ray diffraction RMN NMR GC-MS GC-MS
70	Towards new catalytic systems for the formation of methyl methacrylate from methyl propanoate Coetzee, Jacorien January 2011 (has links) The two stage Lucite Alpha Process for the industrial manufacturing of methyl methacrylate (MMA) represents one of the most efficient technologies currently available for the large scale production of this important chemical commodity. The second stage of this process, which involves the condensation of methyl propanoate (MeP) with formaldehyde over a heterogeneous fixed bed catalyst, however, still shows great scope for improvement. Herein the development of a novel homogeneous catalytic system that would promote the condensation of either propanoic acid or MeP with formaldehyde is explored. Since C–C bond forming reactions which proceed via C–H activation pathways typically display high atom efficiency, our efforts were particularly focussed on employing a functionalisation strategy that is mediated by C–H activation. In the case of propanoic acid, the possibility of achieving regioselective α-methylenation by linking the substrate to phosphorus was evaluated. Thus, a series of acyloxyphosphines and acylphosphites derived from either propionic acid or phenylacetic acid was prepared and, where stability allowed, fully characterised. Some of the resultant simple mixed anhydrides posed problems relating to their stability, and the stabilisation of such ligand systems by using electronic and / or steric effects was therefore explored. In addition, the coordination chemistry and in solution behaviour of Rh(I) and Ru(II) complexes containing these ligands was examined. Similar to the free ligands, complexes derived from these mixed anhydrides rearranged in solution via a number of decomposition pathways, with the specific pathway dependent on the nature of the auxiliary ligands. For most of these complexes, however, ligand decarbonylation was the route of preference for decomposition. Despite the instability of these complexes, a selection of Rh(I) mixed anhydride complexes were assessed for their potential as C-H activation catalysts in reactions aimed at the α-methylenation of saturated carboxylic acids. Furthermore, the stabilisation of Rh(I) mixed anhydride complexes with chelating auxilary ligands, such as bisphosphines or N-substituted diphosphinoamines, was explored. In particular, a series of new Rh(I) mixed anhydride complexes containing dppe, dppb and dppbz as secondary ligands were prepared and the effects of these secondary ligands on the in solution stability of these complexes assessed. As MeP represents the final product in the first stage of the Alpha process and not propanoic acid, the utilisation of PNP iridium pincer complexes in the regioselective sp³ C–H activation of MeP and related esters was also examined. The factors that govern the regioselectivity of such reactions were of great interest to us and, in particular, the effects of water on the reactivity and regioselectivity of these reactions were explored. For MeP, preferential C–H activation of the methoxy group was found to proceed under anhydrous conditions and the catalytic functionalisation of this site with ethene using this activation approach was considered. Formaldehyde, employed in the second stage of the Alpha process, is a difficult substance to manufacture and handle, especially on a large scale. A preliminary study on the in situ production of anhydrous formaldehyde via the catalytic dehydrogenation of methanol was therefore performed. During this study, catalytic systems based on carbonate salts and / or transition metal complexes were considered. In the hope of reducing the number of steps required in the production of MMA, a new one-pot cascade reaction for the indirect α-methylenation of MeP with methanol was developed. Although the production of MMA using this system only proceeded with low efficiency, the obtained results serve as an important proof of concept for future developments in this area. Finally, the capacity of a series of simple bases to catalyse the condensation of MeP with formaldehyde was assessed as part of a fundamental study directed towards determining the factors that govern the efficiency of this reaction. In addition, the extent to which each base effects the deprotonation in the α-position of MeP was determined with the aid of deuterium labelling experiments. Similarly, using sodium propanoate as model base a rough estimate of the kinetics of deprotonation could be made based on the degree of deuterium incorporation over time. These studies suggested that the low efficiency of this condensation reaction is not caused by ineffective deprotonation but rather by the weak nucleophilicity of the generated carbanion. For this reason, attempts to increase the electrophilicity of formaldehyde through Mannich-type condensations reactions involving secondary amine and carboxylic acid additives were made. 547

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