Advances in electroanalytical chemistry

Wang, Yijun

January 2012

This thesis concerns several advances in electroanalytical chemistry which are separated into four parts: the electrochemical investigation of diffusional behaviour, the mechanistic and kinetic study of electrochemistry with room temperature ionic liquids (RTILs), the study of weakly-supported electrochemistry and a comparison of the Butler-Volmer and Marcus-Hush kinetic theories of electron transfer. A study of the diffusional behaviour of electroactive species is essential for further studies, especially in the case when electrochemistry is complicated through ion-pairing interactions between the electroactive species and other electrolytes. In Part II of this thesis, the possibility of the ferricenium ion-paired with perchlorate and hexauorophosphate in acetonitrile was discussed firstly employing chronoamperometric technique. Afterwards, the hexaammineruthenium III/II couple supported by chloride, nitrate and sulfate respectively was studied by a similar method. In order to avoid unwanted ion-pairing effects, room temperature ionic liquids can be applied as solvent, which provide high conductivity by their own ionic nature so that experiments can be conducted without adding additional supporting ions. Because of RTILs have distinctive properties, for example, high viscosity, high conductivity and ionic nature, electrochemistry could be greatly changed compared to those in conventional solvents. Part III of this thesis gives a detailed description of this topic. First, a study of the reduction of 1,4-benzonquinone in 1-ethyl-3-methylimidazolium bis(triuoromethanesulfonyl)imide is presented to show the new mechanistic insight into comproportionation in a electrochemical process. Second, a discussion of the oxidation of hydroquinone in the same RTIL is introduced to suggest a possible ECE scheme which was never reported before. The interest of weakly supported electrochemistry is also well-established, which not only provides another alternative strategy to avert ion-pairings but also offers more physical insights into electrochemical processes. Quantitative methods analysing voltammetries without an excess amount of supporting electrolyte are developed by introducing a migration term into the mass transport equation. In Part IV, new mechanistic insights into the reduction of 2-nitrobromobenzene and the dimerisation of 2,6-diphenylpyrylium in acetonitrile were provide by using weakly-supported cyclic voltammetry. Also, pulse techniques was also adopted to investigate the reduction of cobaltocenium and cobalt(III) sepulchrate, giving an alternative way for electrochemical analysis. A major application of electroanalytical chemistry is investigating electrochemical kinetics. Two kinetic models mostly concerned by electrochemists are Butler-Volmer and Marcus-Hush formalisms. The classic phenomenological model, Butler-Volmer formalism successfully describes most common electron transfer kinetics but shows little reference with nature of the involved species, solution and electrode material, while a more physically insightful theory, the Marcus-Hush formalism, takes species natural properties, for instance, a change of distances or geometry in the solvation or coordination shells of the redox, into account although it requires more complex formulations. Comparative studies of these two theories are presented in Part V in order to improve our understanding of the electron transfer kinetics under different circumstances. First, comparison of cyclic voltammograms of the reduction of europium(III) and 2-methyl-2-nitropropane at mercury microhemispherical electrodes was carried out. Second, square wave and differential pulse voltammetric techniques were also employed to further discriminate the two kinetic models. These studies all find that the symetric Marcus-Hush theory assuming the reactants and products have identical force constant dose not satisfactorily agree with the experimental results. Hence, the introduction of asymmetric Marcus-Hush theory was presented considering different oxidative and reductive reorganization energies, which gives reasonable agreement with experiments and makes this theory more insightful.

541

Réacteur d'électrosynthèse microstructuré : conception, étude et développement appliqués à l'oxydation du 4-méthylanisole / Electrochemical microreactor : design, study and development applied to 4-methylanisole oxidation

Attour, Anis

27 April 2007

L’étude traite la réalisation et la validation d’un microréacteur destiné à l’électrosynthèse organique. Le système électrochimique modèle est l’oxydation du 4-méthylanisole en 4-méthoxy-benzaldéhyde-diméthylacétal. La simulation du comportement théorique d’un réacteur électrochimique travaillant à haute conversion pour l’oxydation du 4-méthylanisole a permis de déterminer les conditions pour lesquelles le réacteur apporte un meilleur rendement. Les essais expérimentaux effectués sur un microréacteur travaillant en continu et à haute conversion ont montré l’influence de la concentration de l’électrolyte support KF sur le rendement de la réaction. Pour un débit optimal de 0,2 ml min-1, une concentration initiale en réactif de 0,1 M et en appliquant un courant égal à 85% du courant théorique nécessaire à convertir totalement le réactif en une seule passe dans la cellule, la sélectivité atteint 86% (pour une conversion de 95%), alors qu’elle n’est que de 68% dans le procédé BASF. / This work concerns the realization and the validation of a microstructured reactor for organic electrosynthesis. The electrochemical reaction is the oxidation of 4-methylanisole to 4-methoxy-benzaldehyde-dimethylacetal. Theoretical behaviour simulations of high conversion thin-gap flow cell of the 4-methylanisole show conditions for which the reactor has best productivity. The experimental tests carried out on high conversion thin-gap flow reactor showed the influence of the supporting electrolyte (KF) concentration on the reaction yield. For an optimal flow rate of 0.2 ml min-1, an initial reagent concentration of 0.1 M and a current equal to 85% of the theoretical current necessary to convert all reagent, it is possible to reach selectivity of 86% with single pass high conversion (95%) , whereas selectivity on BASF process doesn’t exceed 68%.

Microréacteur

Intensification des procédés

Électrolyte support

Électrode segmentée

Microstructured reactor

Process intensification

Supporting electrolyte

Segmented electrode

Weakly supported voltammetry

Limon Petersen, Juan Gualberto

January 2010

This thesis is concerned with dynamic electrochemical experiments with different concentrations of supporting electrolyte. Normally supporting electrolyte is added to a solution in order to avoid undesirable effects as migration and potential drop in solution. However, in the present thesis we focus on the study and understanding of such effects as the concentration of supporting electrolyte decreases. First a theoretical treatment is proposed, based on numerical simulation using the Nernst-Planck- Poisson system of equations. The theoretical treatment is compared with previous works as electroneutrality, the differences between both models are explained. The model is also compared with theoretical results to validate the theoretical treatment. Experimental results of chronoamperometry and cyclic voltammograms are compared with theoretical results obtaining remarkable agreement. Is noteworthy that to the best of the author’s knowledge this is the first time that experimental dynamic voltammetry under weakly supported conditions has been successfully modeled by a theoretical treatment. The electrochemical reaction of a non-charged electroactive species is presented for the system ferrocene/ferrocenium in acetonitrile in which the oxidized and reduced species are soluble in solution, the reaction is studied at different concentrations of supporting electrolyte. Comparison is presented between theoretical simulations and experimental results, for which potential drop in solution is studied. Then systems involving charged electroactive species are treated, in these cases the decrease of supporting electrolyte influence the mass transport of the electroactive species due to migration, comparison between different experimental systems as hexaammineruthenium (III)/(II), cobaltoceniun/cobaltocene and hexacyanoferrate (III)/(II) are presented in comparison with theoretical simulations. More complex mechanistic paths are also investigated, such as deposition and stripping, in which it is established that the level of support required to achieve ‘diffusion only’ voltammetry is on dependence of the concentration of amalgamated electroactive species prior to the stripping step. Comparison between theoretical simulation and experimental results of the deposition and stripping of thallium at a mercury hemisphere are presented, and found to be in good agreement for either chronoamperometry and cyclic voltammetry Simulations are also presented showing the necessary required amount of supporting electrolyte required to achieve ‘diffusion only’ cyclic voltammetry. This is obtained by comparison between diffusion only software and the simulation described in the present thesis. The required amount of supporting electrolyte is shown to depend on the concentration of the electroactive species and supporting electrolyte in the media, the electrode radius, the diffusion coefficient of species and the scan rate. Finally, the cyclic voltammetry in weakly supporting media is used to obtain mechanistic information, by using the migration of electroactive species to differentiate the mass transport of electroactive species to the electrode. The two single electron reductions of anthraquinone in acetonitrile is presented, and the comproportionation mechanistic path is observed in weakly supported media, diffusion only voltammetry is normally unable to present whether this mechanism path takes place, due to the similarity in diffusion coefficients of the electroactive species. In contrast in weakly support conditions the diffusion controlled comproportionation mechanistic path is observed experimentally and constraints for the rate constant are discussed.

541.37

Corrosion and Stress Corrosion Cracking of Carbon Steel in Simulated Fuel Grade Ethanol

Cao, Liu

29 August 2012

No description available.

Engineering

Materials Science

Metallurgy

biofuel

fuel grade ethanol

pitting corrosion

stress corrosion cracking

carbon steel

IR drop

supporting electrolyte

crack growth rate

dissolved oxygen

corrosion potential

chloride