Synthesis, Surface Design and Assembling of Colloidal Semiconductor Nanocrystals

Sayevich, Uladzimir

15 August 2016

The work presented in the thesis is focused on the synthesis of diverse colloidal semiconductor NCs in organic media, their surface design with tiny inorganic and hybrid capping species in solution phase, and subsequent assembling of these NC building units into two-dimensional close-packed thin-films and three-dimensional non-ordered porous superstructures.

info:eu-repo/classification/ddc/540

ddc:540

Développement de nanoparticules de ruthénium comme modèles de catalyseurs pour le craquage de l'eau : approches expérimentale et théorique / Development of ruthenium nanoparticles as catalyst models for the splitting of water : combination of experimental and theoretical chemistry approaches

Gonzalez Gomez, Roberto

11 April 2019

Cette thèse s'inscrit en amont de la problématique de production d'hydrogène (H2) à partir de l'eau. Les réactions impliquées (oxydation de l'eau, WOR et réaction d'évolution de l'hydrogène, HER) requièrent des catalyseurs tels que des nanoparticules (NPs) métalliques. Cette catalyse peut être photoactivée en associant un photosensibilisateur (PS) aux NPs conduisant à des hybrides PS-NPs. Un tel assemblage peut se faire via des groupements acides carboxyliques. Ce travail de doctorat repose sur la combinaison d'outils expérimentaux et théoriques en vue de développer de nouveaux nanocatalyseurs au ruthénium. Notre contribution a consisté à définir une cartographie précise de la surface de Ru NPs stabilisées par des acides carboxyliques avec des chaînes alkyles de longueur différente comme systèmes modèles de catalyseurs PS-NPs pour la photoproduction d'H2 à partir d'H2O. Parmi les principaux objectifs était visée une meilleure compréhension des relations structure/propriétés à l'échelle nanométrique afin d'expliquer les propriétés de surface des NPs et leur viabilité catalytique. Les RuNPs ont été synthétisées par voie organométallique à partir du complexe [Ru(COD)(COT)] comme source de Ru et des acides carboxyliques (éthanoïque, pentanoïque et octanoïque) comme stabilisants. Cette méthode permet la formation de NPs bien contrôlées, fournissant ainsi des systèmes de choix pour des études comparatives fines. Des populations homogènes de RuNPs de taille 1.1 à 1.7 nm ont été obtenues. L'état de surface des NPs a été sondé par différentes techniques analytiques (IR, RMN et WAXS). L'optimisation du ratio [ligand) / [Ru] a permis de disposer de NPs de tailles similaires, et donc de systèmes comparables quel que soit l'acide carboxylique utilisé. Des calculs DFT ont été effectués en parallèle sur un modèle de NP Ru55, dont certains ont alimenté un modèle thermodynamique permettant de s'approcher des conditions expérimentales de température, de pression et de concentration. Une analyse systématique des propriétés des liaisons, des charges atomiques et des états électroniques (DOS, COHP, MPA) a été réalisée. Les calculs des modes de vibration des modèles à base de Ru55 et des déplacements chimiques RMN de clusters [Ru6] ont corroboré et facilité les attributions spectroscopiques expérimentales. Les données spectroscopiques et des études mécanistiques DFT ont montré que les acides carboxyliques interagissent sur la surface métallique sous forme carboxylate. En bon accord, les titrages expérimentaux et théoriques ont montré l'efficacité de l'approche suivie pour cerner l'influence du ligand et de la longueur de la chaîne alkyle sur les propriétés de RuNPs. L'énergie libre de Gibbs de l'adsorption d'hydrogène, un paramètre de référence pour déterminer la viabilité de matériaux pour la catalyse HER, a été calculée par DFT sur des modèles Ru55. Le meilleur nanocatalyseur doit présenter à la fois une surface métallique moyennement encombrée et un ligand avec une longueur de chaîne alkyle intermédiaire, indiquant ainsi comme système le plus prometteur les RuNPs stabilisées par l'acide pentanoïque. Des études d'échange de ligands à la surface de RuNPs stabilisées par l'acide octanoïque ont été réalisées afin de modéliser l'ancrage du PS par un groupe acide carboxylique et complétées par des études théoriques. Les résultats obtenus ont démontré la potentialité de cette approche. Une originalité de ce travail réside dans la combinaison d'études expérimentales et théoriques menées de front pour mieux comprendre la relation structure/propriétés de RuNPs stabilisées par des acides carboxyliques et leur viabilité catalytique pour la production d'H2 à partir d'H2O. Les données obtenues et des résultats catalytiques préliminaires devraient permettre de concevoir des nanocatalyseurs efficaces. Si l'intérêt d'une telle approche a été démontré sur des RuNPs modèles pour le craquage de l'eau, ce travail ouvre d'autres perspectives en nanocatalyse. / This PhD thesis is an upstream study regarding the production of hydrogen (H2) via the water splitting process. The reactions involved (water oxidation, WOR and hydrogen evolution reactions, HER) require efficient catalysts and nanoparticles (NPs) can act so. Such catalysis can be photoactivated by combining photosensitizers (PS) with the NPs leading to hybrid PS-NPs systems, and effective assembling is able via carboxylic acid groups. This work relies on a combination of experimental and theoretical tools to develop novel ruthenium-based nanocatalysts for the water splitting process. Our contribution aimed at achieving a precise mapping of the surface of ruthenium nanoparticles (RuNPs) stabilized by carboxylic acids with an alkyl chain of different length as model systems for the design of PS-NPs catalysts for H2 photoproduction from water. One of the main aims of this PhD was to bring a better understanding of structure/properties relationship at the nanoscale to explain the surface properties of RuNPs stabilized by carboxylic acids and their catalytic viability. RuNPs were synthesized by the organometallic approach using the [Ru(COD)(COT)] complex as metal source and ethanoic, pentanoic and octanoic acids as stabilizers. This synthesis method allows the formation of well-controlled metal NPs, thus providing nanosystems of choice for fine comparative studies. TEM characterization revealed the formation of homogeneous populations of RuNPs in a size range of 1.1 - 1.7 nm. The surface state of the NPs was probed by complementary analytical techniques like IR, NMR and WAXS, leading to a precise mapping of their surface. Optimization studies of the ligand/[Ru] ratio to get NPs with a similar size allowed to have comparable nanosystems whatever the carboxylic acid used as stabilizer and thus to determine the influence of the alkyl chain length. DFT calculations were performed in parallel according to a thermodynamic model fed with DFT energies. Also, a systematic analysis of the bond properties and of the electronic states (Density of States, Crystal Orbital Hamilton Population, atomic charges) was carried out using a Ru55 NP model. DFT calculations of the vibrational features of model RuNPs and of the chemical shifts of model Ru clusters also allowed to secure the spectroscopic experimental assignations. Spectroscopic data and DFT mechanistic studies evidenced that the carboxylic acids lie on the metal surface as carboxylates, together with hydrogen atoms. The results of experimental and theoretical titrations are in good agreement, thus showing the approach followed to be an efficient step to build a model in order to understand the ligand influence on RuNPs properties. Hydrogen adsorption Gibbs free energy, which is a reference parameter to determine the viability of materials for HER catalysis, has been calculated for optimized RuNP structures. The best nanocatalyst revealed to have both, intermediate crowded metal surface and intermediate alkyl chain length for the capping ligand, indicating the RuNPs stabilized by pentanoic acid as the most promising catalyst. Experiments on ligand exchange at the surface of octanoic acid-stabilized RuNPs were also performed in order to model the PS anchoring onto RuNPs through carboxylic acid groups completed by theoretical studies. Results obtained demonstrated the potentiality of this approach. The originality of this work lies with the combination of experimental and theoretical studies in parallel to achieve a better understanding of structure/properties relationship of RuNPs stabilized by carboxylic acids and their catalytic viability for the water-splitting process. Preliminary catalytic results are encouraging, and the data obtained should now allow to design appropriate nanocatalysts. Finally, the interest of this combined approach has been demonstrated through the study of RuNPs for water splitting, but this work opens new opportunities of research in nanocatalysis.

Ruthénium

Nanoparticules

Chimie organométallique

Chimie de coordination

Titrage DFT

Cartographie de surface

Echange de ligands

Hydrogène

Catalyse

Craquage de l'eau

Ruthenium

Nanoparticles

Organometallic Chemistry

Coordination Chemistry

DFT titration

Surface mapping

Ligand exchange

Hydrogen

Catalysis

Water splitting

Detection and speciation of silver in freshwater containing triclosan and thyroid hormone T3

Collins, Patricia Lillian

05 August 2010

In freshwater, there is more opportunity for silver (Ag) to interact with organic ligands than in seawater. Triclosan is an antibiotic agent which resembles thyroid hormone T3 and is finding its way into aquatic systems. Preliminary toxicology studies for the frogSCOPE program suggest that triclosan and nanosilver (nanoAg), also used as an antibiotic agent, may be chemically interacting, as they seem to synergistically increase the endocrine-disrupting abilities already observed independently in each chemical. Ag speciation methods can be used to determine if triclosan or thyroid hormone T3 are interacting with Ag ion (Ag+), which gets released over time by nanoAg. To fully utilize Ag speciation methods, however, total Ag in the sample must also be independently analyzed. Here we investigated a new total Ag analysis using cadmium sulfide quantum dots (CdS QDs) as fluorescence probes in solution. This method promises results in a fraction of the time of the established competitive ligand equilibration-solvent extraction (CLE-SE) technique utilizing PDC- and DDC- to bind Ag and bring it out of solution. Following this investigation were a series of experiments using CLE-SE for total Ag and Ag speciation in well water used to house bullfrog tadpoles in frogSCOPE Ag exposure studies. CLE-SE for Ag speciation was also applied to well water samples containing the two levels of nanoAg or Ag+ used in frogSCOPE Ag exposures, and used in ligand competition experiments to examine the potential of triclosan or T3 to act as strong Ag-binding ligands, as compared to glutathione and EDTA, two known Ag-binding ligands. The results of the latter experiments could be used to determine if either of these could be forming complexes with Ag which increase or decrease their delivery to amphibian cells. The fluorometric method using CdS QDs showed no ideal analytical response to nanomolar Ag+, even when commercial QDs were modified and used, so it could not be applied to our samples. Using CLE-SE for total Ag, the well water used as a base for toxicity studies in frogSCOPE contained Ag below the method detection limit of 5 pM. Using the speciation variation of the CLE-SE method, no evidence of naturally-occurring ligands which could produce extractable (hydrophobic) or non-extractable (hydrophilic) Ag complexes was found in this well water. EDTA and glutathione responded as model Ag-binding ligands to form non-extractable hydrophilic Ag complexes in fresh water. T3 behaved like these model ligands, while triclosan enhanced the extractability of Ag in the presence of certain concentrations of the added ligand, DDC-. In another set of experiments, coordination of Ag by triclosan or T3 was not detectable within that analytical window. These results suggest that ionic Ag released over time by nanoAg may be binding T3 and preventing it from reaching its receptor, but confirming the interaction of triclosan and Ag+ will require additional experiments using different analytical windows.

silver speciation

cadmium sulfide quantum dots

silver toxicity

silver in freshwater

nanosilver

frogSCOPE

triclosan

thyroid hormone T3

fluorometry

ICP-MS

competitive ligand exchange

solvent extraction

Elaboration et étude de matériaux hybrides orientés et nanostructurés d'intérêt pour l'électronique organique / Elabotation and characterization of oriented and nanostructured hybrid materials of interest for organic electronics

Hartmann, Lucia

04 April 2012

Le but de cette thèse était d’élaborer et d’étudier des films minces hybrides orientés et nanostructurés composés d’un polymère semi-conducteur, le poly(3-hexylthiophène) regiorégulier (P3HT) et de nanocristaux semiconducteurs de CdSe (sphères, bâtonnets). Pour cela, deux méthodes ont été mises en œuvre: la croissance épitaxiale directionnelle et le brossage mécanique. Les films de P3HT purs épitaxiés et brossés se différencient en termes de nanomorphologie, d’ordre cristallin et de structure. Les premiers présentent une morphologie lamellaire et une structure de fibre où les chaînes conjuguées sont alignées suivant l’axe de fibre. Les films brossés ne présentent pas de structure lamellaire et les domaines cristallins sont orientés préférentiellement «flat-on». Ces différences se reflètent dans les propriétés optiques des films épitaxiés et brossés. Le degré d’orientation des films brossés dépend fortement du poids moléculaire et une forte anisotropie du transport de charges a été observée. Les films hybrides épitaxiés sont nanostructurés avec localisation des nanocristaux dans les zones amorphes du P3HT. Par ailleurs, l’analyse par tomographie électronique de ces films montre une structure en bicouche avec une couche hybride surmontée d’une couche de P3HT pur. Les films hybrides brossés montrent clairement un alignement des nanobâtonnets de CdSe et des chaînes du P3HT parallèlement à l’axe du brossage. Les degrés d’orientation du P3HT et des nanobâtonnets sont corrélés et dépendent de la proportion en nanoparticules indiquant que c’est la matrice polymère qui induit l’orientation des nanobâtonnets. / The aim of this thesis was to elaborate and characterize hybrid oriented and nanostructured thin films composed of a semiconducting polymer, regioregular poly(3-hexylthiophène) (P3HT) and semiconducting CdSe nanocrystals (spheres, rods). Two orientation methods were used: directional epitaxial crystallization and mechanical rubbing. Epitaxied and rubbedfilms of pure P3HT show strong differences in terms of nanomorphology, crystalline order and structure. Epitaxied films possess a lamellar morphology, a 3D crystalline order and fiber symmetry where the P3HT backbones (cP3HT) are aligned along the fiber axis. Rubbed films do not show a lamellar morphology and have a 2D crystalline order with crystalline domains preferentially oriented “flat-on” relative to the substrate. These differences are reflected in the optical properties of the films. The orientation degree achieved in rubbed films strongly depends on the molecular weight of the polymer. There is also a strong anisotropy of the charge transport properties. Regarding hybrid epitaxied layers, we observed a nanostructuration with a localization of the CdSe nanocrystals into the amorphous zones of the P3HT. Moreover, electron tomography analysis shows that such films have a bilayer structure with a hybrid layer covered by pure P3HT. In rubbed hybrid films prepared with nanorods, the long axis of the nanorods as well as the P3HT backbone are oriented parallel tothe rubbing direction. The degree of in-plane orientation of the rods and of the P3HT matrix match closely and depend on the proportion of CdSe nanrods in the films. These results suggest that the P3HT matrix enforces the orientation of the rods.

Organique électronique

Polymère semi-conducteur

Poly(3-hexylthiophène)

Orientation des polymères

Brossage mécanique

Nanocristaux semiconducteurs

Epitaxie

Ligand

Organic electronics

Semi-conducting polymers

Poly(3-hexylthiophene)

Orientation of polymers

Mechanical rubbing

Epitaxy

Ligand exchange

Semi-conducting nanocrystals

621.38

668.9

Synthesis, optical and morphological characterization of pbse quantum dots for diagnostic studies: a model study

Ouma, Linda Achiengꞌ

January 2013

>Magister Scientiae - MSc / In this study PbSe quantum dots (QDs) were successfully synthesized via the organometallic and aqueous routes. Optical characterization was carried out using photoluminescence (PL) spectroscopy, structural and morphological characterization were carried out using X-ray diffraction (XRD) and transmission electron microscopy (TEM). Energy-dispersive X-ray spectroscopy (EDS) was used to determine the composition of the QDs. All the synthesized QDs were found to have emissions within the near-infrared region of the spectrum (≥1000 nm) with most of them being less than 5 nm in size. The aqueous synthesized QDs had a perfect Gaussian emission spectrum with a FWHM of ~23 nm indicating pure band gap emission and narrow size distribution respectively. The QDs were determined to have a cubic rock-salt crystal structure consistent with bulk PbSe. The aqueous synthesized QDs were however not stable in solution with the QDs precipitating after approximately 48 h. The organometallic synthesized QDs were transferred into the aqueous phase by exchanging the surface oleic acid ligands with 11-mercaptoundecanoic acid ligands. The ligand exchanged QDs were however stable in solution for over two weeks. The effects of reaction parameters on the optical and structural properties of the organometallic synthesized QDs were investigated by varying the reaction time, temperature, ligand purity, lead and selenium sources. It was observed that larger QDs were formed with longer reaction times, with reactions proceeding faster at higher reaction temperatures than at lower temperatures. Varying the ligand purity was found to have minimal effects on the properties of the synthesized QDs. The lead and selenium sources contributed largely to the properties of the QDs with lead oxide producing spherical QDs which were smaller compared to the cubic QDs produced from lead acetate. TBPSe was seen to produce smaller QDs as compared to TOPSe. The cytotoxity of the synthesized QDs was determined following the WST-1 cell viability assay with the QDs being found to be non-toxic at all the tested concentrations

PbSe

Quantum dots (QDs)

Semiconductor nanocrystals (NCs)

Near-infrared (NIR)

Organometallic synthesis

Aqueous synthesis

Ligand exchange

Photoluminescence spectroscopy (PL)

3-Mercaptopropionic acid (MPA)

11-Mercaptoundecanoic acid (MUA)

Water-soluble tetrazolium salt (WST-1)

Synthesis and Ligand Engineering of Colloidal Metal Chalcogenide Nanoparticles for Scalable Solution Processed Photovoltaics

Ryan Gupta Ellis (9175325)

09 September 2022

<p>As global population continue to rise, the demand for energy is slated to increase substantially. To combat climate change, large amounts of renewable energy will be needed to feed this growing demand. Of renewable energy sources, photovoltaics are well positioned to meet this increasing demand due to the immense abundance of solar energy incident on earth. However, existing energy intensive, low throughput, and costly manufacturing techniques for photovoltaics may pose a barrier to continued large scale implementation.</p> <p>Solution processing has emerged as a promising photovoltaics fabrication technique with high throughput, high materials utilization, and lower cost than existing vacuum-based methods. Thin film photovoltaic materials such as Cu(In,Ga)(S,Se)₂ and CdTe have both been fabricated using various solution processing methods. Of the various solution processing routes, colloidal metal chalcogenide nanoparticles have demonstrated promise as a hydrazine-free route for the solution processing of high efficiency Cu(In,Ga)(S,Se)₂ solar cells. However, conventional solution processing with colloidal nanoparticles has long suffered from anionic and carbonaceous impurities, stemming from legacy synthesis methods. The work in this dissertation aims to solve these issues through the development of novel synthetic methods, ligand engineering, and ultimately improved scalability through slot-die coating.</p> <p> Typical colloidal syntheses rely on the use of metal salts as precursors such as metal halides, nitrates, acetates, and so forth, where the anions may incorporate and alter the electrical properties of the targeted nanomaterials. In this work, the recent advances in amine-thiol chemistry and its unique ability to solubilize many metal containing species are expanded upon. Alkylammonium metal thiolate species are easily formed upon addition of monoamine and dithiol to elemental Cu, In, Ga, Sn, Zn, Se, or metal chalcogenides such as Cu₂S and Ag₂S. These species were then used directly for the synthesis of colloidal nanoparticles without the need for any additional purification. The metal thiolate thermal decomposition pathway was studied, verifying that only metal chalcogenides and volatile byproducts are formed, providing a flexible route to compositionally uniform, phase pure, and anionic impurity-free colloidal nanoparticles including successful syntheses of In₂S₃, (In_xGa_1–x)₂S₃, CuInS₂, CuIn(S_xSe_1–x)₂, Cu(In_xGa_1–x)S₂, Cu₂ZnSnS₄, and AgInS₂. </p> <p>However, further impurities from deleterious carbonaceous residues originating from long chain native ligands were still a persistent problem. This impurity carbon has been observed to hinder grain formation during selenization and leave a discrete residue layer between the absorber layer and the back contact. An exhaustive hybrid organic/inorganic ligand exchange was developed in this work to remove tightly bound oleyalmine ligands through a combination of microwave-assisted solvothermal pyridine ligand stripping followed by inorganic capping with diammonium sulfide, yielding greater than 98% removal of native ligands via a rapid process. Despite the aggressive ligand removal, the nanoparticle stoichiometry remained largely unaffected when making use of the hybrid ligand exchange. Scalable blade coating of the ligand exchanged nanoparticle inks from non-toxic dimethyl sulfoxide inks yielded remarkably smooth and crack free films with RMS roughness less than 7 nm. Selenization of ligand exchanged nanoparticle films afforded substantially improved grain growth as compared to conventional non-ligand exchanged methods yielding an absolute improvement in device efficiency of 2.8%. Hybrid ligand exchange nanoparticle-based devices reached total-area power conversion efficiencies of 12.0%.</p> <p>While extremely effective in ligand removal, ligand exchange pathways increase process complexity and solvent usage substantially, which may limit the cost advantage solution processing aims to provide. Further synthesis improvement was developed through a ligand exchange free, direct sulfide capped strategy. Using sulfolane as a benign solvent, CuInS₂ nanoparticles with thermally degradable thioacetamide ligands were synthesized using thermal decomposition of isolated metal thiolates from Cu₂S and In precursors. Through gentle thermal treatment, these ligands decomposed into non-contaminating gaseous byproducts leaving carbon free nanoparticle films without the need for ligand exchange.</p> <p>With the development of virtually contamination free colloidal nanoparticle inks, focus was shifted to scalability using slot die coating. Unlike typical lab-scale coating techniques such as spin coating, slot die coating is a widely used industrial coating technique with nearly 100% materials utilization, and high throughput roll-to-roll compatibility. A custom lab-scale slot-die coater was used to rapidly proof coating conditions, which were rapidly analyzed for uniformity using absorbance scanning in conjunction with profilometry. A cosolvent chlorobenzene/dichlorobenzene ink was developed to yield highly uniform, crack free thin films from non-ligand-exchanged Cu(In,Ga)S₂ nanoparticles, which were finished into devices with champion total are efficiencies of 10.7%. To the best of our knowledge, this represents the first report of slot die coated Cu(In,Ga)(S,Se)₂ photovoltaics. The methods presented in this work offer a pathway towards low impurity, high efficiency, scalable solution processed Cu(In,Ga)(S,Se)₂ photovoltaics to enable low cost renewable energy.</p>

Nanochemistry

Supramolecular chemistry

Nanoparticle

CIGS

CIGSSe

Photovoltaics

Solution Processing

Slot-Die

Ligand Exchange

Selenization

Complexes cationiques POCOP de nickel : synthèse, caractérisation, réactivité et étude catalytique

Lapointe, Sébastien

06 1900

Ce mémoire traite de la chimie des complexes pinceurs de nickel (II) cationiques ayant un ligand de type POCOP. Elle se divise en deux parties. La première traite de la synthèse, de la caractérisation et de la réactivité des complexes cationiques pinceurs de Ni(II) de type POCOP (POCOP = 1,3-bis(phosphinitobenzene), où C fait partie d’un cycle benzénique et est lié au métal, et P est un ligand phosphoré aussi lié au métal). Ces complexes ont un ligand acétonitrile coordonné au centre métallique et sont du type [(R-POCOPR’)Ni(NCMe)][OSO2CF3], où R est un substituant du cycle benzénique et R’ est un substituant sur le ligand phosphoré (R’ = iPr: R = H (1), p-Me(2), p-OMe(3), p-CO2Me(4), p-Br(5), m,m-tBu2(6), m-OMe(7), m-CO2Me(8); R’ = t-Bu : R = H (9), p-CO2Me(10)). Les complexes cationiques sont préparés en faisant réagir le dérivé Ni(II) neutre correspondant R-(POCOPR’)Ni-Br avec Ag(OSO2CF3¬) dans l’acétonitrile à température ambiante. L’impact des groupements R et R’ du ligand POCOP sur la structure et sur les propriétées électroniques du complexe a été étudié par spectroscopies RMN, UV-VIS et IR, analyse électrochimique, et diffraction des rayons X. Les valeurs de fréquence du lien C≡N (ν(C≡N)) augmentent avec le caractère électroattracteur du complexe, dans l’ordre 7 < 3 ~ 2 ~ 6 < 1 < 5 ~ 8 < 4 et 9 < 10. Ces résultats sont en accord avec le fait qu’une augmentation du caractère électrophile du centre métallique devrait résulter en une augmentation de la donation σ MeCN→Ni. De plus, les complexes cationiques montrent tous un potentiel d’oxydation Ni(II)/Ni(III) plus élevé que leurs analogues neutres Ni-Br. Ensuite, une étude d’équilibre entre un complexe neutre (R-POCOPR’)NiBr et un complexe cationique [(R-POCOPR’)Ni(NCMe)][OSO2CF3] démontre l’échange facile des ligands MeCN et Br. La deuxième partie de ce mémoire consiste en deux chapitres. Le premier (Chapitre 3) est une étude structurelle permettant une meilleure compréhension du mécanisme d’hydroamination des oléfines activées promue par les complexes présentés au chapitre 1, suivi de tentatives de synthèse de nouveaux composés POCOP cationiques comportant un ligand amine et nitrile, et de déplacement du groupement amine par un groupement nitrile. Le deuxième chapitre (4) décrit la réactivité et la cinétique de la réaction d’hydroamination et d’hydroalkoxylation d’oléfines activées, qui permet ainsi de mieux comprendre l’impact des différentes variables du système (groupements R et R’, température, substrats, solvent, etc.) sur la réactivité catalytique. / This thesis describes the chemistry of nickel (II) cationic pincer complexes bearing a POCOP ligand. The content is divided into two parts. The first part (chapter 2) concerns the synthesis, characterization and reactivities of nickel (II) cationic POCOP pincer complexes with an acetonitrile ligand coordinated to the metal center via the nitrile moiety, [(R-POCOPR’)Ni(NCMe)][OSO2CF3] where R is a ring substituent and R’ is a P-substituent (R’ = iPr : R = H (1), p-Me(2), p-OMe(3), p-CO2Me(4), p-Br(5), m,m-tBu2(6), m-OMe(7), m-CO2Me(8); R’ = t-Bu : R = H (9), p-CO2Me(10)). The cationic complexes are synthetized by reacting the neutral nickel (II) bromide derivatives R-(POCOPR’)Ni-Br with Ag(OSO2CF3) in acetonitrile at room temperature. The impact of R and R’ groups of the POCOP ligand on the structure and electronic proprieties of the complexes has been studied by NMR, UV-Vis and IR spectroscopy, as well as by single crystal x-ray diffraction studies and cyclic voltammetry measurements. The observed ν(C≡N) values were found to increase with the increasing electron-withdrawing nature of R, i.e., in the order 7 < 3 ~ 2 ~ 6 < 1 < 5 ~ 8 < 4 and 9 < 10. This trend is consistent with the anticipation that enhanced electrophilicity of the nickel center should result in an increase in net MeCN→Ni σ-donation. It is also interesting to note that all cationic complexes show a much higher Ni(II)/Ni(III) oxidation potential than their neutral Ni-Br analogues. Following this, an equilibrium study is presented that shows the facile exchange of the MeCN/Br ligands between the charge-neutral and cationic complexes (R-POCOPR’)NiBr and [(R-POCOPR’)Ni(NCMe)][OSO2CF3]. The second part of this thesis consists of two chapters describing, respectively, structural studies that are relevant to our understanding of the mechanism of hydroamination reactions promoted by the title complexes (chapter 3), and reactivity and kinetic studies aimed at understanding the impact of different variables (R and R’; temperature; substrates; solvent; etc.) on the Michael-type hydroamination and hydroalkoxylation of acrylonitrile and its substituted derivatives (chapter 4). Chapter 3 will also discuss the attempted synthesis of new amine and nitrile POCOP cationic and neutral complexes, as well as the facile displacement of the amine moiety by a nitrile.

Nickel (II) Cationique

Complexes Pinceurs

Complexes POCOP Cationiques de Nickel

Synthèse

Caractérisation

Effets Électroniques

Effets Stériques

Échange de Ligands

Oxydation par Ferrocène

Hydroamination

Hydroalkoxylation

Études Mécanistiques

Composés Amine

Amines

Études Cinétiques

Nickel (II)

Pincer Complexes

Cationic POCOP Nickel Complexes

Synthesis

Characterization

Electronic Effects

Steric Effects

Ligand Exchange

Oxidation by Ferrocene

Mechanistic Investigations

Amine Complexes

Kinetic Studies