Optimization of the interfacial electron transfer by nanostructuring and surface modification / Optimisation de transfert de charge interfacial par nanostructuration et modification de surface

Aceta, Yara

29 October 2018

C'est la surface, et non le matériau qui interagit avec l'environnement. Par conséquent, en modifiant la surface d'un matériau de manière contrôlée, nous pouvons moduler ces interactions avec son environnement. Les sels d'aryles diazonium semblent très adaptés pour modifier les propriétés de surface de matériaux de par leurs diversités structurelles et leur capacité à modifier des surfaces conductrices par électrochimie. Ce travail de thèse se concentre sur l'étude du transfert électronique au travers de couches organiques de différentes épaisseurs (monocouches, couches ultraminces et multicouches), générées par électro-réduction de sels d'aryles diazonium. La molécule électroactive étudiée peut être alors soit fixée à la surface du matériau ou en solution. Différentes méthodes électrochimiques ont été utilisées au cours de cette thèse : CV, EIS et SECM. Dans un premier temps, l'étude des propriétés électrochimiques de surfaces carbonées modifiées par des monocouches d'alkyle-ferrocène a été entreprise dans différents solvants ; ainsi que leur évaluation pour des applications en stockage d'énergie. La deuxième étude s'intéresse à l'utilisation d'une approche « bottom-up » pour la fabrication de surfaces organisées. Des substrats de carbone et d'or ont été modifiés par électro-réduction d'un sel d'aryle diazonium pré-organisé en forme de tétraèdre. Ceci aboutit à l'obtention d'un film organique ultra-mince possédant des propriétés de tamisage moléculaire et de rectification de courant électrochimique vis-à-vis de sondes redox en solution. La troisième étude s'est ensuite focalisée sur la réaction de réduction du dioxygène et de ses intermédiaires, qui présentent un intérêt général aussi bien dans des processus naturels qu'en industrie. La détection de ces intermédiaires a été entreprise par SECM, utilisant une stratégie « d'empreinte » utilisant différentes couches organiques sensibles. L'influence du potentiel appliqué et de l'électrolyte a été étudiée. Dans ce travail, nous avons démontré que les propriétés électrochimiques de sondes redox en solution ou greffées à la surface d'un matériau peuvent être modulées par l'utilisation de couches organiques. Ces recherches fondamentales présentent un intérêt dans des domaines tels que le stockage d'énergie et la catalyse. / It is the surface, not the bulk material that interacts with the surrounding environment; hence by altering the surface in a controlled manner we can modulate the properties of the material towards its environment. Aryldiazonium salts are suitable to tailor the surface properties since their structural diversity and their electrochemically-assisted bonding ability to modified conducting surfaces. This thesis focuses on the study of the electron transfer through different aryl layers by aryldiazonium electro-reduction at three different thickness levels, monolayer, near-monolayer, and multilayer, when the electroactive molecule is attached to the surface or in solution. Three different electrochemical methods have been used throughout this thesis, CV, EIS and SECM. The first study of this thesis focused on the investigation of the electrochemical properties of alkyl-ferrocene on-carbon monolayers in different solvents and its evaluation for improving the global charge density of carbon materials for energy storage applications. The second study used a bottom-up approach for the fabrication of well-organized surfaces. Carbon and gold substrates were modified by electro-reduction of a tetrahedral-shape preorganized aryldiazonium salt resulting in an ultrathin organic film that showed molecular sieving and current rectification properties towards redox probes in solution. The third study then focused on the oxygen reduction reaction and its intermediates, which are of general importance in natural and industrial processes. Detection of intermediates was achieved by SECM in a foot-printing strategy based on the use of different sensitive aryl multilayers. The role of the applied potential and electrolytes was investigated. Here we have demonstrated that the electrochemical properties of redox probes attached to a surface or in solution can be modulated by introducing aryl layers allowing fundamental research investigations of interest in fields such as energy storage and catalysis.

Aryldiazonium

Électrochimie

Monocouche

Stockage d'énergie

Nanostructuration

Réduction de l'oxygène

Aryldiazonium

Electrochemistry

Monolayer

Energy storage

Nanostructuring

Oxygen reduction

The Modification of Gold Surfaces via the Reduction of Aryldiazonium Salts

Paulik, Matthew George

January 2007

This thesis presents the study of films derived from the reduction of aryldiazonium salts at gold surfaces. The properties of bare polycrystalline surfaces were investigated via the observation of the electrochemical oxidation and reduction of the gold. Films derived from diazonium salts were electrochemically grafted to the gold surface. The structure and stability of these interfaces was examined through the use of redox probes, gold oxide electrochemistry and water contact angle measurements. The spontaneous reduction of aryldiazonium salts at gold surfaces was investigated and the possible applications it presented towards printing and patterning of the gold surface with films were explained. Polycrystalline gold surfaces were prepared and subjected to various treatments, to observe the behaviour of gold oxide formation and reduction at the surface. Various effects on the surface structure were observed after treatment in solvents and electrolyte solutions. The surface structure of the gold atoms frequently changed due to the high mobilities of the gold atoms, and it is difficult to achieve a reproducibly stable surface. The electrochemical modification of gold surfaces via the reduction of aryldiazonium salts was investigated. Surfaces were modified with methylphenyl and carboxyphenyl films and exposed to various treatments. Monitoring the gold oxide reduction changes enabled the surface coverage of modifier directly attached to the surface to be calculated. The films appear to be stable, loosely packed and porous. The films are flexible in nature; redox probe responses showed reversible changes after repeated sonication in solvents of differing polarities and hydrophilicities. Contact angle measurements further support the notion of films that can reorganise in response to their environment. The spontaneous reduction of aryldiazonium salts at gold surfaces was observed. Film coverage was significantly lower at the spontaneously grafted surface than for films grafted electrochemically. Gold surfaces were successfully modified via microcontact printing, and surface coverages similar to the spontaneously grafted film were achieved. Microcontact printing was also used to pattern surfaces with films derived from diazonium salts. Feature sizes down to 100 µm were successfully achieved.

Gold

aryldiazonium salt

wettability

microcontact printing

electrochemical modification

spontaneous modification

Modification of surfaces with thin organic films by reaction with aryldiazonium salts

Lehr, Josua

January 2010

In this work, the modification of conducting substrates with thin (nanometer thick) aryl films via reaction with aryldiazonium salts was investigated. Two methods were used: modification by electro-reduction of the aryldiazonium salts and modification by spontaneous reaction of aryldiazonium the salts with the surface at open circuit potential. The majority of the studies were undertaken using p-nitrobenenze diazonium salt, which gives electro-active nitrophenyl (NP) films at the surface that can be detected and characterized by cyclic voltammetry. Films prepared spontaneously on carbon and gold electrodes at open circuit potential were characterized by electrochemistry, atomic force microscopy (AFM), X-ray photoelectron spectroscopy (XPS) and water contact angle measurements. At both carbon and gold, spontaneous modification proceeds via electron transfer from the surface to the diazonium salt.Furthermore, on both types of surface, spontaneously prepared NP films were found to be loosely packed multilayers of less than 5 nm in thickness. The spontaneous reaction was utilized for the patterning of carbon, gold, silicon and copper surfaces by microcontact printing (μCP) with diazonium salts. The presence of spontaneously formed films upon printing was confirmed by cyclic voltammetry and AFM. The films were demonstrated to be useful for the tethering of further molecules to the surface. Patterns prepared by μCP were imaged using scanning electron microscopy (SEM) and condensation figures. The preparation of two-component systems, with different chemical functionalities attached to different, well-defined, regions of the surface, was demonstrated. The optimization of the long term activity of glucose oxidase hydrogels by covalent attachment of the hydrogels to modified carbon electrodes was investigated. Covalent attachment was demonstrated, but the resulting electrode-hydrogel surfaces did not show long-term activities superior to those for physisorbed hydrogels. It is suggested that the limiting factor for long-term hydrogel activity is not adhesion of the hydrogel to the surface, but degradation of enzymatic activity by H2O2.

Thin Films

Aryldiazonium Salts

Surface Modification

Patterning

Surface Functionalisation

The Modification of Gold Surfaces via the Reduction of Aryldiazonium Salts

Paulik, Matthew George

January 2007

This thesis presents the study of films derived from the reduction of aryldiazonium salts at gold surfaces. The properties of bare polycrystalline surfaces were investigated via the observation of the electrochemical oxidation and reduction of the gold. Films derived from diazonium salts were electrochemically grafted to the gold surface. The structure and stability of these interfaces was examined through the use of redox probes, gold oxide electrochemistry and water contact angle measurements. The spontaneous reduction of aryldiazonium salts at gold surfaces was investigated and the possible applications it presented towards printing and patterning of the gold surface with films were explained. Polycrystalline gold surfaces were prepared and subjected to various treatments, to observe the behaviour of gold oxide formation and reduction at the surface. Various effects on the surface structure were observed after treatment in solvents and electrolyte solutions. The surface structure of the gold atoms frequently changed due to the high mobilities of the gold atoms, and it is difficult to achieve a reproducibly stable surface. The electrochemical modification of gold surfaces via the reduction of aryldiazonium salts was investigated. Surfaces were modified with methylphenyl and carboxyphenyl films and exposed to various treatments. Monitoring the gold oxide reduction changes enabled the surface coverage of modifier directly attached to the surface to be calculated. The films appear to be stable, loosely packed and porous. The films are flexible in nature; redox probe responses showed reversible changes after repeated sonication in solvents of differing polarities and hydrophilicities. Contact angle measurements further support the notion of films that can reorganise in response to their environment. The spontaneous reduction of aryldiazonium salts at gold surfaces was observed. Film coverage was significantly lower at the spontaneously grafted surface than for films grafted electrochemically. Gold surfaces were successfully modified via microcontact printing, and surface coverages similar to the spontaneously grafted film were achieved. Microcontact printing was also used to pattern surfaces with films derived from diazonium salts. Feature sizes down to 100 µm were successfully achieved.

Gold

aryldiazonium salt

wettability

microcontact printing

electrochemical modification

spontaneous modification

Arilação de Heck da N-Metoxicarbonil-2-Carboximetil-1,2,5,6-Tetraidropiridina com sais de Arildiazonio. Aplicação na sintese da (+ -)-Paroxetina / Heck arylation of the N-Methoxycarbonyl-3-Carboxymethyl-1,2,5,6-Tetrahydropyridine with aryldiazonium salts. Application to the synthesis of (+ -)-Paroxetine

Pastre, Júlio Cezar, 1979-

06 August 2018

Orientador: Carlos Roque Duarte Correia / Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Quimica / Made available in DSpace on 2018-08-06T00:38:56Z (GMT). No. of bitstreams: 1 Pastre_JulioCezar_M.pdf: 2844371 bytes, checksum: 6abfb0e87d60113816e3b01d9a02d6b9 (MD5) Previous issue date: 2005 / Mestrado / Quimica Organica / Mestre em Química

Paroxetina

Arilação de Heck

Sais de Arildiazonio

Paroxetine

Heck arylation

Aryldiazonium salts

Fonctionnalisation d'hétérocycles par catalyse organométallique et photorédox / Heterocycle functionalizations by organometallic and photoredox catalyses

Languet, Morgan

28 November 2017

Dans le cadre de nos travaux, deux méthodes de fonctionnalisation d’hétérocycles par catalyse organométallique ont été développée. Dans un premier temps, l’introduction d’un motif oléfinique en position C3 sur des hétérocycles à 5 chaînons a été réalisée grâce à un système catalytique basé sur l’utilisation d’un sel de rhodium(III) et d’un sel d’argent. Malgré quelques limites au niveau du champ d’application de la méthode, cette dernière se trouve être particulièrement efficace pour l’introduction d’acrylate en position C3 sur ces hétérocycles. L’emploi ici d’un carbamate comme groupe directeur nous a permis d’effectuer un grand nombre de réaction de post-fonctionnalisation tels que des couplages croisés catalysés par des sels de nickel et de fer. La seconde partie de nos travaux concerne la mise au point d’une réaction d’arylation de 2-quinolone en position C3 par catalyse photorédox. Dans des conditions particulièrement douces (température ambiante, sans additifs), l’arylation de ces 2-quinolones a été effectuée en utilisant des sels d’aryldiazonium tétrafluoroborate comme précurseur de radicaux aryles. Des expériences de contrôles, des mesures de spectres d’absorption UV-visible ainsi qu’une expérience de type ON/OFF ont également été entrepris afin d’élucider le mécanisme de cette réaction d’arylation photocatalysée. / The work presented in this manuscript concerns two methods of functionalization of heterocycles by using organometallic catalysis. Firstly, the introduction of an olefinic moiety at the C3 position of 5-membered heterocycles was achieved by a catalytic system based on the use of a rhodium(III) salt and a silver salt. Despite some limitations in the scope, this method was found to be particularly effective for the introduction of an acrylate group at the C3 position of these heterocycles. Furthermore, the use of carbamate as a directing group, has allowed a large number of post-functionalization reactions such as cross-couplings catalyzed by nickel and iron salts. The second part of our work was devoted to the arylation of 2-quinolone at the C3 position by photoredox catalysis. More particularly, under mild conditions (ambient temperature, without additives), the arylation of these 2-quinolones was carried out using aryldiazonium tetrafluoroborate salts as a precursor of aryl radicals. Control experiments, measurements of UV-visible absorption spectra and an ON/OFF experiment were also performed to elucidate the mechanism of this photocatalysed arylation.

Catalyse

Organométallique

Rhodium

Hétérocycles

Photorédox

Aryldiazonium

Catalysis

Photoredox

Heterocycles

547

Preparation and characterization of aryldiazonium electroreduction-derived and metallophthalocyanine-modified carbon surfaces : application to nitrate electrochemical reduction in acidic aqueous media / Préparation et caractérisation des électrodes de carbone vitreuses modifiées par la réduction électrochimique des sels de diazonium et par abrasion physique des phtalocyanines : application à la réduction électrochimique des nitrates dans le milieu aqueux acide

Hussain, Riaz

15 November 2012

Ce travail de thèse concerne la préparation et caractérisation des électrodes de carbone vitreuses (GC) modifiées par les films de groupements aryl (substitués) ou par phtalocyanines des métaux (MPc) et l'évaluation de leurs activités catalytiques envers la réduction électrochimique des nitrates dans les milieux aqueux acides. Les techniques adoptées pour la modification de surface du substrat (le GC) consistent à la réduction électrochimique des sels de diazonium ou à l'abrasion physique de la surface contre la poudre des MPc. En faisant intervenir un mécanisme complexe, y compris les phénomènes d'adsorption du réactif et du produit sur la surface, l’électroréduction de sels de diazonium entraîne au greffage des groupements aryls sur la surface. Les analyses voltamétriques détaillées ont rendu possible de conclure, décisivement pour la première fois, que la réduction commence à se faire sur la surface entière et, selon la concentration du diazonium et/ou l'efficacité du greffage, peut continuer à se faire à traverse les ouvertures microscopiques générés parmi les groupements aryl greffés sur la surface durant l'étape précédente de réduction (...) / This thesis work concerns about the preparation, characterization and catalytic activities evaluation of (substituted) aryl and metallophthalocyanines films-modified glassy carbon (GC) electrodes towards nitrate electrochemical reduction in acidic aqueous media. The surface modification techniques adopted consisted of the electroreduction of 4-substituted aryl diazonium salts and the metallophthalocyanine (MPc) powder abrasive adsorption. Through a complex mechanism involving the reactants and products adsorptions on the substrate surface, the electroreduction of aryl diazonium salts leads to the covalent attachment of mono as well as multilayers of aryl groups on the substrate surface. Detailed voltammetric investigations enabled to conclude, decisively for the first time, that the diazonium cation reduction begins to take place on the bulk (whole) surface and, depending upon the concentration and/or the products grafting efficiency, may continue to take place across the microscopic pinholes formed among the aryl groups grafted on the surface during the previous reduction step, thereby explaining the origin of the two reduction peaks in the voltammograms on GC surface. Electrochemical characterization of 4-nitrophenyl(NP)-modified surfaces in various types of aqueous media shed light over a number of mechanistic aspects of the process. Some new electrochemical evidences of the complications of surface coverage determination of redox centers from their electrochemical responses and of the role of aqueous electrolyte species transport on the responses have been presented. Some new phenomena or observations such as identification of the regions of votammograms corresponding to aminophenyl and hydroxyaminophenyl formation of the surface bound NP groups reduction, identification of the method of surface bound NP groups surface coverage estimation from the total width at half wave maximum (or electron transfer coefficient) of the responses, identification of the mechanistic aspects governing the differences of voltammetric behaviors of surface bound NP layers and the solution phase nitrobenzene, electrochemical (and XPS) evidences of the presence of azo type functionalities in the aryl films prepared from aryldiazonium electroreduction were also noticed. Barrier characters of the aryldiazonium electroreduction-derived N,N-dimethylaminophenyl-, nitrophenyl- and aminophenyl-modified surfaces towards ferricyanide, hexaammineruthenium and proton electroreductions in aqueous media indicate to the existence of electrostatic interactions among the surface bound and the solution phase ionic species. However, upon negative potential applications (such as those of water or nitrate reductions) surface attached films are partly or completely lost from the surface, as evidenced by the analytical scale measurements as well as from potentiostatic electrolysis of nitrate reduction in acidic aqueous media. Concerning the MPc-modified GC surfaces, the analytical scale measurements showed that among the phthalocyanines of copper, Iron and Nickel, the one of Cu is an optimizing material for the nitrate electrochemical reduction in, not previously reported, acidic aqueous media. The catalytic activity of MPc powders towards nitrate reduction in these media, which varies in the order CuPc > FePc > NiPc > GC appears to be related to the mental center and not with the phthalocyanine ring

Abrasion physique des phtalocyanines

Nitrates

Milieu aqueux acide

Modified Glassy carbon electrodes

Aryldiazonium salts electroreduction

Nitrates

Aqueous acidic media