Global ETD Search

51	Dirhodium(II,II) Complexes as Electrocatalysts for Sustainable Energy Applications: Tunable Selectivity For H<sup>+</sup> or CO<sub>2</sub> Reduction Witt, Suzanne Elizabeth January 2017 (has links) No description available. Chemistry Inorganic Chemistry Analytical Chemistry alternative energy sustainable energy catalysis electrochemistry chemistry rhodium water splitting CO2 reduction inorganic chemistry
52	SILVER HALIDE NANOCUBES: UNIQUE PLATFORM FOR DEVELOPING HIGH-PERFORMANCE CATALYSTS Abeyweera, Sasitha Chathuranga January 2020 (has links) Controlled synthesis of functional nanostructures is of paramount interest due to their novel properties and efficient functionalities. The size and morphology of each particle in the nanoscale contribute to their optical and electronic properties. Also, the collective arrangement of these nanostructures in 3D space maximizes active sites available for the cost-effective catalysis. Recent advances in the field show a vast range of nanostructures with unique designs that affect their catalytic properties. In this dissertation, utilizing silver halides as a unique platform to develop high-performance catalysts were discussed with their respective synthesis strategies, structural evolution, and structure-related properties. Initially, we synthesized well-defined silver chlorobromide (AgCl0.5Br0.5) nanostructures investigating the effects of various reaction parameters on the synthesis. Simple reaction parameters were overlooked to gain additional controllability on determining the morphology of the nanocrystals regardless of the composition. Thus, the influence of the size and exposed surface facets was investigated towards photocatalytic activity performing methylene blue degradation on AgCl0.5Br0.5 with different sizes and morphologies, under visible light. Then, the ability to use these AgCl0.5Br0.5 nanocubes were investigated as a reactive and sacrificial template for the synthesis of nanoplates and nanoshells. As an example, fast precipitation reaction between Ag+ and benzenethiol (BT–) results in an uncontrollable growth leading to aggregated structures. The low solubility and the planer surfaces of the silver halide cubes were utilized to reduce the reaction rate and promote the growth of layered AgBT as plates, which can be organized into hollow nanostructures. Time-dependent microscopic and spectroscopic measurements showed the structural evolution and associated kinetics of the conversions. Developing a comprehensive understanding enabled generalizing the procedure to synthesize other silver-based hollow nanostructures. Mechanistic studies showed two different hollowing mechanisms involving, that depends on the anion being exchanged. The degree of nucleation and the crystal structure of silver-sulfur compounds determined the relative diffusion of ions leading to their overall size and morphology. The hollow morphology was shown to have higher stability with a large surface area relative to its aggregated solid counterpart. Next, highly porous Ag nanostructures were synthesized electrochemically, using silver thiolate nanocages. High porosity and their arrangement as plates enhanced available active sites and mass transport for CO2 electroreduction. Furthermore, the strategy was extended to design bimetallic nanostructures with enhanced bimetallic boundaries where selectivity of ethanol formation from CO2 electroreduction can be increased. Overall, the study explores the novel approaches to utilize chemical and physical properties of silver halides for various material designs that determines their enhanced performance. / Chemistry Chemistry Materials Science Chemistry, Physical Co2 Reduction Hollow Nanoshells Nano Material Synthesis Porous Silver Silver Halide Silver Thiolates
53	SURFACE AND STRUCTURAL MODIFICATION OF CARBON ELECTRODES FOR ELECTROANALYSIS AND ELECTROCHEMICAL CONVERSION Zhang, Yan 01 January 2018 (has links) Electrocatalysis is key to both sensitive electrochemical sensing and efficient electrochemical energy conversion. Despite high catalytic activity, traditional metal catalysts have poor stability, low selectivity, and high cost. Metal-free, carbon-based materials are emerging as alternatives to metal-based catalysts because of their attractive features including natural abundance, environmental friendliness, high electrical conductivity, and large surface area. Altering surface functionalities and heteroatom doping are effective ways to promote catalytic performance of carbon-based catalysts. The first chapter of this dissertation focuses on developing electrode modification methods for electrochemical sensing of biomolecules. After electrochemical pretreatment, glassy carbon demonstrates impressive figures-of-merit in detecting small, redox-active biomolecules such as DNA bases and neurotransmitters. The results highlight a simplified surface modification procedure for producing efficient and highly selective electrocatalysts. The next four chapters focus on evaluating nitrogen-doped carbon nano-onions (𝑛-CNOs) as electrocatalysts for oxygen reduction and CO2 reduction. 𝑛-CNOs exhibit excellent electrocatalytic performance toward O2 to H2O reduction, which is a pivotal process in fuel cells. 𝑛-CNOs demonstrate excellent resistance against CO poisoning and long-term stability compared to state-of-the-art Pt/C catalysts. In CO2 electrochemical conversion, 𝑛-CNOs demonstrate significant improvement in catalytic performance toward reduction of CO2 to CO with a low overpotential and high selectivity. The outstanding catalytic performance of 𝑛-CNOs originates from the asymmetric charge distribution and creation of catalytic sites during incorporation of nitrogen atoms. High contents of pyridinic and graphitic N are critical for high catalytic performance. This work suggests that carbon-based materials can be outstanding alternatives to traditional metal-based electrocatalysts when their microstructures and surface chemistries are properly tailored. Glassy Carbon Electrochemical Treatment Nitrogen-Doped Carbon Nano-Onion Oxygen Reduction Reaction CO2 Reduction Reaction Biochemistry Catalysis and Reaction Engineering Nanoscience and Nanotechnology
54	Designing a new electrochemical cell for the study of enzyme that reduces CO2 / Conception d'une nouvelle génération de cellules électrochimiques pour l'étude des enzymes qui réduisent le CO2 Fadel, Mariam 13 November 2018 (has links) Le monoxyde de carbone déshydrogénase (CODH) catalyse la réduction réversible du dioxyde de carbone par son site actif. En utilisant une méthode électrochimique appelée voltammétrie de film protéique, nous étudions le mécanisme enzymatique de CODH en immobilisant l'enzyme à une surface d'électrode de graphite où le transfert direct d'électrons est possible. Traditionnellement, pour empêcher la déplétion du substrat à l'électrode, les électrochimistes utilisent des électrodes tournantes (RDE). Cependant, comme la CODH est très active, même la RDE ne peut pas empêcher l'épuisement, ce qui masque les caractéristiques cinétiques importantes de l’enzyme. Nous ne pouvons pas résoudre le problème avec RDE, puisque nous l’utilisons déjà à la vitesse maximum. Par conséquent, nous devons concevoir une nouvelle cellule électrochimique. Pour cela, nous avons utilisé des simulations de dynamique des fluides computationnelles pour explorer diverses géométries afin d'en trouver une appropriée. Nous avons commencé par valider notre méthode numérique avec la solution théorique bien définie de la cellule réelle de RDE. Après la bonne validation, nous avons déterminé les vitesses de transport de masse au sein de plusieurs géométries et à basé sur l'optimisation des paramètres géométriques, nous avons atteint notre conception appropriée. Ce nouveau prototype a une électrode graphite uniformément accessible avec un taux de transport trois fois plus rapide que le RDE à des vitesses de solution acceptables. Nous avons construit, mis en place avec succès le système pour caractériser ses performances de transport, et trouvé un excellent accord entre les résultats numériques et expérimentaux / Carbon monoxide dehydrogenase (CODH) catalyzes the reversible reduction of carbon dioxide by its active site. Thus, CODH participates in the first step of fuel production. Using an electrochemical method called protein film voltammetry, we study the enzymatic mechanism of CODH by immobilizing the enzyme at a graphite electrode surface where direct electron transfer is possible. Traditionally, to prevent depletion of the substrate at the electrode, electrochemists use rotating electrodes (RDE). However, since CODH is very active, even RDE cannot prevent depletion, which masks the important kinetic characteristics of the enzyme and complicates the analysis of the enzymatic response.We cannot solve the problem with RDE, since we already use it at maximum speed. Therefore, we must completely change our approach and design a new electrochemical cell. For this, we used computational fluid dynamics (CFD) simulations to explore various geometries to find a suitable one. We began by validating our numerical method with the well-defined theoretical solution of the real cell of RDE. After good validation, we determined the mass transport velocities within several proposed geometries of the flow cell of hydrodynamic channel and jet electrodes. Based on the optimization of geometric parameters, we have achieved our proper design of jet electrode. This new prototype has a uniformly accessible graphite electrode with a transport rate three times faster than the RDE at acceptable solution speeds. We have successfully built and implemented the system to characterize its transport performance. We found an excellent agreement between the numerical and experimental results Transport de masse Cellules électrochimiques Réduction de CO2 Dynamique des fluides numérique (CFD) Électrode hydrodynamique Études cinétiques Mass transport Electrochemical cells CO2 reduction Computational fluid dynamics (CFD) Hydrodynamic electrodes Kinetic studies.
55	Nanomatériaux hybrides TiO2/[Ru(bpy)3]2+ associés à [Cr(ttpy)2]3+ ou [Mn(ttpy)(CO)3Br] ou au pyrrole : synthèse, études spectroscopiques et applications pour la conversion de l'énergie solaire / TiO2/[Ru(bpy)3]2+ based hybrid nanomaterials associated with [Cr(ttpy)2]3+ or [Mn(ttpy)(CO)3Br] or pyrrole moiety : Synthesis, spectroscopic studies and applications in solar energy conversion Le Quang, Long 21 December 2017 (has links) Ce mémoire vise à montrer l’intérêt de nanoparticules (NPs) de TiO2 comme plateforme pour immobiliser dans un environnement proche des complexes de coordination pouvant interagir par transfert d’électron photoinduit. Nous nous sommes intéressés à l’étude de nanomatériaux hybrides associant le complexe [Ru(bpy)3]2+ (bpy = 2,2'-bipyridine) comme photosensibilisateur aux complexes [Cr(ttpy)2]3+ ou [Mn(ttpy)(CO)3Br] (ttpy = 4'-(p-tolyl)-2,2':6',2''-terpyridine) comme accepteurs d'électrons. Pour immobiliser les différents complexes à la surface du TiO2, une fonction acide phosphonique a été introduite sur une des bipyridines du centre [Ru(bpy)3]2+ et sur la terpyridine des complexes [Cr(ttpy)2]3+. L’étude des processus de transferts de charges photo-induits sous irradiation en lumière visible sur le colloïde TiO2/RuII montre que l'état à charges séparées (e-)TiO2/ RuIII possède une longue durée de vie, ce qui rend possible l'utilisation des charges dans des réactions successives d’oxydation ou de réduction. Notamment l’irradiation du colloïde TiO2/RuII en présence de [Cr(ttpy)2]3+ et de triéthanolamine (TEOA) comme donneur d'électron sacrificiel permet la réduction à deux électrons du [Cr(ttpy)2]3+. Par la suite, le complexe [Cr(ttpy)2]3+ est immobilisé sur les NPs de TiO2/RuII pour former un assemblage RuII/TiO2/CrIII au sein duquel les processus de transfert d'électrons photo-induits sont étudiés. De manière à proposer un système pour la réduction photocatalytique du CO2, le complexe [Mn(ttpy)(CO)3Br] a été co-immobilisé avec le [Ru(bpy)3]2+ suivant une approche de chimie sur surface pour former le colloïde RuII/TiO2/MnI. Ce système présente une excellente sélectivité vis-à-vis du HCOOH comme seul produit de la photoréduction du CO2 en présence de 1-benzyl-1,4-dihydronicotinamide (BNAH) comme donneur d'électron sacrificiel. Un système hybride associant le [Ru(bpy)3]2+ portant des fonctions pyrroles et immobilisé sur TiO2 a également été synthétisé et étudié. Sous irradiation lumineuse, le transfert de charges (e-)TiO2/[Ru-pyr]3+ permet d’induire la polymérisation du pyrrole. Le nanocomposite TiO2/poly(Ru-pyr) obtenu et déposé sur une électrode génère, en présence de TEOA, un photocourant anodique stable de plus de 10 μA.cm-2. L’ensemble des résultats montre que les NPs de TiO2 peuvent être un moyen d’assembler des complexes dans un environnement proche en limitant les interactions à l’état fondamental, mais permettant des transferts d’électrons photoinduits entre eux. Suivant les potentiels redox des différents composants, les transferts d’électron ont lieu soit via la nanoparticule soit en surface de celle-ci. / This thesis aims to investigate the possibility of using TiO2 nanoparticles (NPs) as a platform to immobilize proximal coordination complexes that can interact with each other by photoinduced electron transfer. We have studied hybrid nanomaterials combining [Ru(bpy)3]2+ (bpy = 2,2'-bipyridine) as a photosensitizer and [Cr(ttpy)2]3+ or [Mn(ttpy)(CO)3Br (ttpy = 4'-(p-tolyl)-2,2':6',2''-terpyridine) as electron acceptors. To immobilize the various complexes on the surface of TiO2, a phosphonic acid functional group was introduced on one of the bipyridines of the [Ru(bpy)3]2+ center and on the terpyridines of the [Cr(ttpy)2]3+ complex. Under visible light, the TiO2/RuII colloid undergoes a photo-induced charge transfer process leading to a long-lived charge separation state (e )TiO2/RuIII, which makes it possible to be engaged in successive oxidation or reduction reactions. In particular, the visible irradiation of the TiO2/RuII colloid in the presence of [Cr(ttpy)2]3+ and triethanolamine (TEOA) as a sacrificial electron donor allows the two-electron reduction of [Cr(ttpy)2]3+. Subsequently, the [Cr(ttpy)2]3+ complex has been immobilized on the TiO2/RuII NPs to form a RuII/TiO2/CrIII assembly in which the photoinduced electron transfer processes were investigated. In order to propose a system for the photocatalytic reduction of CO2, the [Mn(ttpy)(CO)3Br] and [Ru(bpy)3]2+ complexes were co-immobilized on TiO2 NPs following a chemistry on surface approach to form a RuII/TiO2/MnI triad. Under irradiation at 470 nm, this system exhibits excellent selectivity towards HCOOH as the only product of CO2 photoreduction in DMF/TEOA solvent mixture, in the presence of 1-benzyl-1,4-dihydronicotinamide (BNAH) as a sacrificial electron donor. Another hybrid system linking a [Ru(bpy)3]2+ unit to two pyrrole functions and being immobilized on TiO2 has also been synthesized and studied. Under visible light, the transient (e-)TiO2/[Ru-pyr]3+ species induce the polymerization of pyrrole to form a TiO2/poly(Ru-pyr) nanocomposite. The nanocomposite deposited on an electrode generates, in the presence of TEOA, a stable anodic photocurrent of more than 10 μA.cm-2. All the results show that TiO2 NPs can be used to associate different complexes in a close environment by limiting the interactions in the ground state but allow photoinduced electron transfer processes between them. Depending on the redox potentials of the different components, the electron transfer takes place either through the semiconducting NPs or on the surface. Nanoparticules de TiO2 Transfert d’électron photoinduit Réduction du CO2 Photophysique Spectroscopie RPE Photoelectrode TiO2 nanoparticles Photoinduced electron transfer CO2 reduction Photophysics EPR spectroscopy Photoelectrode 540 530
56	Studies on the Reactivity of a Bis–Mesityl Imidazolyl Carbene Intermediate toward Carbon Dioxide and Stability of the Resulting Carboxylate Ka, Seon Young 23 August 2019 (has links) No description available. Analytical Chemistry Chemistry Climate Change Bis-mesityl imidazolyl carbene Imidazolium-2-carboxylate synthesis CO2 adduct Hydrolytic stability Reductive conversion of CO2 CO2 reduction
57	Understanding the Role of Lattice Defects and Metal Composition Ratio on the Photochemistry of CuFeO<sub>2</sub> toward Solar Energy Conversion Fugate, Elizabeth Anne 11 September 2020 (has links) No description available. Chemistry Delafossite CuFeO2 charge-carrier dynamics transient absorption spectroscopy Cu vacancy O interstitial acetate CO2 reduction formate product selectivity metal composition ratio photo-physics annealing conditions heterojunction structure
58	Estimating CO2 reductions from renewable energy sources : The impact of power system nonlinearities / Uppskattning av förnybara energikällors inverkan på koldioxidutsläppen från elsystemet : en undersökning av icke-linjära faktorer Berglund, Kristoffer January 2022 (has links) Replacing conventional generation with renewable generation in power systems is essential for reducing CO2 emissions. It is important to know how effective renewables are in reducing CO2 emissions. Since CO2 reduction cannot be measured directly, different methods have been used to estimate reduction of CO2 emissions. The two most common methods are econometric models and dispatch models. Econometric models apply regression analysis using historical data for CO2 emissions, power production, and electricity demand to estimate CO2 reduction. On the other hand, dispatch models are detailed optimization simulations of power systems where the objective is to calculate the cost-optimal dispatch of the power plants. The dispatch model finds the optimal dispatch for a base case and counterfactual case. In the counterfactual case, the renewable generation in the system is modified. From the difference in CO2 emissions between the two cases, an estimation of CO2 reduction can be made. Recent studies have shown that dispatch models and econometric models can give different estimations of CO2 reduction. However, these studies did not include several factors that can increase CO2 emissions, such as; transmission constraints, security requirements, and non-linear factors. Examples of non-linear factors are; minimum dispatched energy of generating units, start up emissions, minimum up- and downtime for generating units, and energy generated during start-up and shut-down. This thesis examines if there is an agreement between econometric models and dispatch models for estimating CO2 reduction and if the agreement changes when more non-linear factors are considered. To examine these questions a systematic comparison has been done. Two econometric models are constructed, a linear econometric model and a polynomial linear econometric model. The polynomial linear econometric model is constructed to take into account non-linear factors. Eight dispatch models are constructed with increasing modelling complexity. Four model versions do not include any non-linear factors and four include non-linear factors. The results showed that the agreement between econometric and dispatch models is fairly good, except for versions that contain transmission constraints. The simulation is executed in a fictional test system that is not dimensioned for wind power generation at the given buses. Therefore is possible that transmission constraints impacts the reduction of CO2 too heavily. Furthermore, the results show that the non-linear factors contribute to CO2 emission and consequently lower the estimation of CO2 reduction. However, no conclusion can be made if the agreement between econometric and dispatch models divert when more non-linear factors are considered. / Världens utsläpp av CO2 måste minska för att inte jorden ska drabbas av drastiska klimatförändringar som temperaturhöjningar. Idag står elproduktionen för ungefär en fjärdedel av världens utsläpp av CO2. Därmed måste dagens elproduktion och elkraftsystem minska sina utsläpp av CO2 . Ett viktigt verktyg för att kraftsystem ska minska sina utsläpp av CO2 är expansion av förnybar elproduktion. Dock så går det inte att mäta direkt hur mycket CO2-utsläppen minskar vid expansion av förnybar elproduktion. Därför har flera olika estimeringsmetoder utvecklats för att uppskatta CO2-reduktion. De två vanligaste metoderna är ekonometriska modeller och produktionssimuleringsmodeller. Ekonometriska modeller använder sig av regressionsanalys med historiska tidsserier som; CO2 -utsläpp, kraftproduktion och elförbrukning för att uppskata CO2 -minskningen. Produktionssimuleringsmodeller är detaljerade optimeringssimuleringar där avsikten är att beräkna den kostoptimala användningen av kraftverk i ett system. Tidigare studier har visat att ekonometriska modeller och produktionssimuleringsmodeller kan ge olika uppskattningar av CO2 -reduktion. Dock har produktionssimuleringsmodellerna i studierna inte tagit hänsyn till flera faktorer som kan påverka CO2-utsläppen, som t.ex. överföringsbegränsningar, säkerhetsbegräsningar och icke-linjära faktorer. Exempel på icke-linjära faktorer är minimal produktion av energi för varje kraftverk, CO2 -utsläpp vi uppstart, minimal upp- och nertid och produktion vid uppstart och nedstänging för varje generator. Den här uppsatsen undersöker om de två metoderna ekonometriska modeller och produktionssimuleringsmodeller liknade uppskattningar av CO2 -reduktion och hur överrenstämmelsen mellan modellerna påverkas när man beaktar icke-linjära faktorer. För att försöka besvara dessa frågor har en systematisk jämförelse utförts. Två ekonometriska modeller har konstruerats, en linjär och en polynom-linjär ekonometrisk modell. Den polynom-linjära ekonometriska modellen tar i beaktning icke-linjära faktorer. Åtta produktionssimuleringsmodeller har konstruerats och de åtta olika modellerna har formulerats i en ökande ordning av noggrannhet. Fyra av modellerna tar inte hänsyn till några icke-linjära faktorer och fyra av modellerrna tar hänsyn till icke-linjära faktorer. CO2 reduction Dispatch model Econometric model Unit commitment CO2-reduktion ekonometriska modeller produktionssimuleringsmodeller Elektroteknik och elektronik
59	Greenhouse gas Reduction in Infrastructure Projects : With a case study of California High-Speed Rail / Klimatgasreducering i infrastrukturprojekt : Med en fallstudie av California High-Speed Rail Balian, Daniel January 2017 (has links) Infrastructure projects are today major contributors to global warming. However, various strategies for reduction of greenhouse gas emission are available, as described in sustainability assessment schemes and performed in infrastructure projects. Beyond the choice of methodology, greenhouse gas reduction represents an important challenge, namely to engage involved actors. The establishment of a common sustainability policy, reflected in procurement requirements could be a solution. However, often in subject of complications such as misunderstandings or increased cost. Impres, a research project aiming to streamline the process of greenhouse gas reduction in the infrastructure sector, conducts case studies around the world in which useful methods and examples are assimilated. In cooperation with Impres, the present report includes the case study of California High-Speed Rail (CHSR). The aim of this report is to compare strategies for greenhouse gas reduction of sustainability assessment schemes for infrastructure projects, and evaluate the feasibility as procurement requirements. Furthermore, to identify corresponding processes of greenhouse gas reduction in the case study of CHSR, as well as revealing important factors towards realization. The course of work involves a study of the schemes Envision, BREEAM Infrastructure, CEEQUAL, IS Rating System as well as the standard PAS 2080. Regarding the case study, the sustainability policy, procurement requirements and project reports are the main used sources. Moreover, qualitative interviews with involved actors have been performed in California. Finally, to create a comparative matrix for greenhouse gas reduction processes, standards ISO and PAS 2080 have been reviewed. The results show that greenhouse gas criteria of the studied schemes not are mandatory to perform in anyone but PAS 2080. Which means that further requisites might be needed in order for the schemes to be useful as procurement requirements. Furthermore, the outlining of processes reveals a weakness in the setting of a greenhouse gas reference point, and while every scheme includes a greenhouse gas quantity assessment, there is a difference in the priority of reduction. Regarding CHSR, an exclaimed policy goal is to perform climate neutral construction. While procurement requirements are limited to quantification of emitted greenhouse gases and the use of effective construction machinery, which is insufficient to meet the goal. Nevertheless, the Authority in charge is performing CO2 compensating measures, such as planting trees. Finally, a variety of driving forces, success factors and challenges for realizing greenhouse gas reduction have been identified. For example, personal motivation and legislation as driving forces. Whereas, sustainability as a core mission, experience and communication are seen as success factors, and resistance to transfer sustainability goals to procurement is an exclaimed challenge. As a conclusion, sustainability assessment schemes do have certain processes for greenhouse gas reduction in common. However, they present criteria with different degrees of obligation, affecting feasibility as procurement requirements. In CHSR, similar processes are found, where further reduction of greenhouse gases can be achieved, especially by an optimized choice of construction materials. In the end, personal motivation seems to be an important factor for introducing and realizing greenhouse gas reduction goals in infrastructure projects. / Impres Carbon management CO2 reduction Greenhouse gases LCA Infrastructure Sustainability Assessment Scheme Rating System Value Chain Actors Stakeholders. Infrastructure Engineering Infrastrukturteknik Climate Research Klimatforskning
60	Electrochemical synthesis of organic compounds using CO2 and biomass as feedstock Li, Junnan 05 1900 (has links) Le CO2 et la biomasse sont abondants dans la nature. La conversion de ces deux éléments constitutifs en carburants ou en produits chimiques à valeur ajoutée par des méthodes électrochimiques est essentielle pour atténuer la crise énergétique et réduire la pollution de l'environnement, ainsi que pour atteindre la carbone neutralité. Au cours des dernières décennies, de nombreux efforts ont été consacrés à ce domaine, mais la plupart d'entre eux se concentrent sur la conception de catalyseurs et l'amélioration des performances, et seules quelques recherches se concentrent sur de nouvelles réactions ou sur le mécanisme de ces réactions. Ici, nous développons une série de nouvelles réactions et étudions les mécanismes de ces réactions en utilisant la spectroscopie in situ, les principaux résultats sont les suivants : 1) Les réactions de réduction du furfural ont été menées en utilisant une feuille de Cu électrochimique comme catalyseur, et l'alcool furfural (FA, efficacité faradique, FE : 43,0%) et le 2-méthylfurane (MF, FE : 57,5%) ont été obtenus après électrolyse sous -0,43V (par rapport à l'électrode à hydrogène réversible, RHE). Les effets des différentes facettes du catalyseur sur la sélectivité ont été étudiés, et le Cu (110) produit préférentiellement de l'AF, tandis que les défauts sont les sites actifs pour la formation de MF. La spectroscopie Raman operando a montré que la production de FA et de MF partage le même intermédiaire à l'étape initiale, avec différents sites actifs conduisant aux différentes voies entre les étapes intermédiaires et suivantes et générant différents produits. 2) Des produits de liaison C-N (acétamide et formamide) ont été obtenus par la réaction de réduction du CO2 (CO2RR) avec la combinaison du substrat NH3 et des électrocatalyseurs commerciaux à base de nanoparticules de Cu ou de CuO. Avec l'optimisation, la FE maximale de ces deux produits est de ~10% au total, et la meilleure condition de réaction est 50mg Cu NPs, 1M KOH, avec 0.3M NH3, à -0.78V (vs. RHE) pendant 30 mins. L'IR in situ a montré que la formation de formamide et de formate partage le même intermédiaire, et que la production d'acétamide et d'acétate subit une voie de réaction similaire. 3) L'hydroxyméthanesulfonate (HMS), le sulfoacétate (SA) et le méthanesulfonate (produits de liaison C-S, FE représente 6% au total) ont été obtenus par le couplage CO2RR avec l'ajout de sulfite (SO32-), et des NPs de Cu2O synthétisées par la méthode de chimie humide ont été utilisées comme électrocatalyseurs. Parmi ces trois composés à liaison C-S, le HMS est le principal produit, la FE pouvant atteindre un maximum de 6 %. Le XRD in situ a montré que Cu0 est l'espèce active pour le processus de couplage C-S. Les calculs operando Raman et DFT ont montré que CHOH est l'intermédiaire clé dans la formation de la liaison C-S, et que le couplage entre CHOH et SO32- est l'étape qui détermine le taux. / CO2 and biomass are abundant in nature. Conversion of these two building blocks into fuels or value-added chemicals by electrochemical methods is essential for alleviating the energy crisis and reducing environmental pollution, and achieving carbon neutrality. In the past few decades, much effort has been devoted to this field, but most of this focuses on the design of catalysts and improvement of the performances, and only few research thrusts focus on new reactions or the mechanism of these reactions. Herein, we develop a series of new reactions and investigate the mechanisms of these reactions by using in-situ spectroscopy, the main results are shown as follows: 1) Furfural reduction reactions were conducted by using an electrochemical roughed Cu foil as the catalyst, and furfural alcohol (FA, Faradaic efficiency, FE: 43.0%) and 2-methylfuran (MF, FE: 57.5%) were obtained after electrolysis under -0.43V (vs. reversible hydrogen electrode, RHE). The effects of different facets on the selectivity were investigated, and Cu (110) is preferential to produce FA, while defects are the active sites for the formation of MF. Operando Raman spectrum showed that the production of FA and MF share the same intermediate at the initial stage, with different active sites leading to the pathway differential on the intermediate of the following steps and generating different products. 2) C-N bond products (acetamide and formamide) were obtained by CO2 reduction reaction (CO2RR) with the combination of NH3 reactants and commercial Cu or CuO nanoparticle (NPs) electrocatalysts. The maximum FE of these two products is ~ 10% in total. With optimization, we found a higher pH, thicker catalyst layer, and larger size of cations are beneficial to the production of acetamide. This can be attributed to the higher production of C2 intermediate and further leads to a higher FE of acetamide. In-situ IR showed that the formation of formamide and formate share the same intermediate, and the production of acetamide and acetate undergoes a similar reaction pathway. The mechanism can help to design the new next generation catalyst with a higher efficiency, which is beneficial to the future application of this reaction in chemical industry. Nitrate and nitrite are used instead of ammonia as nitrogen sources to produce C-N bond compounds, which suggests that this reaction provides a new possibility for organic synthesis. In all, this reaction expands the scope of the CO2RR application, and is also good for the development of organic synthesis. 3) Hydroxymethanesulfonate (HMS), sulfoacetate (SA) and methanesulfonate (C-S bond products, FE is 6% in total) were obtained by coupling CO2RR with the addition of sulfite (SO32-), and Cu2O NPs which synthesized by the wet chemistry method were used as electrocatalysts. Among these three C-S bond compounds, HMS is the main product, FE can reach 6% maximum. In-situ XRD showed that Cu0 is the active species for C-S coupling process. Operando Raman and DFT calculation further showed that CHOH is the key intermediate in the C-S bond formation, and the coupling between CHOH and SO32- is the rate-determining step. The discovery of reaction intermediates opens up the possibility of designing highly efficient catalysts, which can promote the application of this reaction in real industries. Also, this reaction provides a new possibility to synthesize C-S bond products, which have the potential to partially replace traditional organic synthetic routes with greener and more sustainable procedures. Réduction du furfural Réaction de Réduction du CO2 Spectroscopie Operando Raman Spectroscopieinfrarouge In Situ Mécanisme Furfural Reduction CO2 Reduction Reaction Operando Raman In-situ infrared Spectroscopy Mechanism Chemistry / Chimie (UMI : 0485)

Search results