Carbon dioxide capture and utilization technologies are necessary to create a truly circular economy. The electrochemical reduction of carbon dioxide to formate is an appealing carbon utilization... Show moreCarbon dioxide capture and utilization technologies are necessary to create a truly circular economy. The electrochemical reduction of carbon dioxide to formate is an appealing carbon utilization method as it can be performed at room temperature and pressure, it only requires two electrons, and it has a high atom efficiency. This reaction has been known and studied for decades, but no commercial process is currently practiced.This thesis reviews work that has been performed in the field of electrocehmical reduction of CO2 toward formate and reviews how a gas diffusion electrode functions. A gas diffusion layer production method is explored for ways to tune the characteristics of the gas diffusion layer. A design of experiments is used to explore how the catalyst layer can interact with the gas diffusion layer. The best results (100% CE at 400mA/cm2) are scaled-up from 10 cm2 to 200 cm2. Contaminants in an industrial CO2 stream are studied using density funcitonal theory to determine their potential to poison electrocatalysts known to convert CO2 to formate. Show less
In this thesis, we consider various (electro)chemical phenomena at surfaces and nanoparticles and their underlying atomistic processes, which we studied using first-principles methods such as... Show moreIn this thesis, we consider various (electro)chemical phenomena at surfaces and nanoparticles and their underlying atomistic processes, which we studied using first-principles methods such as density functional theory. These phenomena range from CO2 reduction to C2 and C3 species, through solvation of adsorbates on various surface features of late transition metals, to the impact of graphene on hydrogen evolution reaction, cathodic corrosion and surface oxidation of Pt. With our thermodynamic and kinetic calculations, we provide explanations for experimental observations by unraveling underlying phenomena, support novel computational methods and techniques, and propose new atomic structures that explain prior findings and provide inroads into future electrocatalytic research. Show less
Artificial photosynthesis has recognised potential to produce green and sustainable fuels from earth-abundant resources such as water, carbon dioxide (CO2), and sunlight. In an artificial... Show moreArtificial photosynthesis has recognised potential to produce green and sustainable fuels from earth-abundant resources such as water, carbon dioxide (CO2), and sunlight. In an artificial photosynthetic system, two half-reactions, such as water oxidation and proton reduction or CO2 reduction, have to be combined. To achieve such a system, it is crucial to have: a) efficient light-harvesting by the photosensitiser, b) stable catalysts for the oxidation and the reduction reaction, c) unidirectional proton and electron transport between the oxidation and the reduction site, ideally by a recyclable electron relay, d) efficient charge separation, and e) a strong, photostable membrane that does not leak molecular components. In natural photosynthesis, these requirements are achieved altogether using compartmentalisation, which consists in embedding the key components of the system, i.e. for green plants the oxygen evolving complex, photosystem I and II, and the natural electron relays, around the lipid bilayer of the thylakoid membrane. The use of spherical lipid membranes (such as liposomes) as biological mimics of the thylakoid membrane is a promising approach to confine half-reactions, facilitate charge separation, and avoid charge recombination and other undesired side-reactions. In the research described in this thesis, it was attempted to realise a full artificial photosynthetic system based on liposomes and several of the key intermediate steps were achieved: 1) unidirectional electron transfer across a liposomal membrane from an electron donor encapsulated in the interior of the liposome to an electron acceptor located outside (Chapter 2), and 2) photocatalytic reduction of CO2 (Chapter 3) and of protons (Chapter 4) at the surface of liposomes. Special attention was paid in Chapter 2 and Chapter 5 to the question of the (photo)stability of the membrane and light-induced leakage. Show less
This thesis focuses on the synthesis, characterization and performance towards CO2 electroreduction of mono and bi-metallic particles based on p-block metals. With an industrial perspective in mind... Show moreThis thesis focuses on the synthesis, characterization and performance towards CO2 electroreduction of mono and bi-metallic particles based on p-block metals. With an industrial perspective in mind, we try to synthesize particulate, high surface area materials with clean, scalable synthesis methods where possible and test their performance in H-Cell and gas diffusion electrode flow cell configurations. With a combination of characterization techniques, we find possible explanations for the catalytic behaviors. Show less
This dissertation focused on computational methods based on first principles calculations using the Density Functional Theory (DFT) framework. Emphasis was laid on affordable methods that can... Show moreThis dissertation focused on computational methods based on first principles calculations using the Density Functional Theory (DFT) framework. Emphasis was laid on affordable methods that can provide a tradeoff between computational expense and accuracy. Specifically, we investigated solvation effects near the surface of the electrode, used thermodynamic cycles to compute solution-phase energies and also proposed a workflow to detect gas-phase errors on the free energies of target molecules. We used these simple methods to study complex adsorption processes at the PdMLPt(111) electrode surface. DFT and experimental studies (performed by Dr. Chen from our group) were crucial to guide the investigation forward. Show less
The electrocatalytic reduction of carbon dioxide is widely studied for the sustainable production of fuels and chemicals. Metal ions in the electrolyte influence the reaction performance, although... Show moreThe electrocatalytic reduction of carbon dioxide is widely studied for the sustainable production of fuels and chemicals. Metal ions in the electrolyte influence the reaction performance, although their main role is under discussion. Here we studied CO2 reduction on gold electrodes through cyclic voltammetry and showed that, without a metal cation, the reaction does not take place in a pure 1 mM H2SO4 electrolyte. We further investigated the CO2 reduction with and without metal cations in solution using scanning electrochemical microscopy in the surface-generation tip-collection mode with a platinum ultramicroelectrode as a CO and H2 sensor. CO is only produced on gold, silver or copper if a metal cation is added to the electrolyte. Density functional theory simulations confirmed that partially desolvated metal cations stabilize the CO2– intermediate via a short-range electrostatic interaction, which enables its reduction. Overall, our results redefine the reaction mechanism and provide definitive evidence that positively charged species from the electrolyte are key to stabilize the crucial reaction intermediate. Show less
With the energy transition toward a renewable energy supply and a CO2-neutral economy, electrification of the energy system is rising in importance, which leads to the challenge of long-term... Show moreWith the energy transition toward a renewable energy supply and a CO2-neutral economy, electrification of the energy system is rising in importance, which leads to the challenge of long-term storage of renewable electricity. A promising option is the electrochemical conversion of biomass or carbon dioxide in chemicals as energy carrier. In this research, catalysis of the electrochemical CO2 reduction was studied to obtain liquid fuels. In this fundamental study we discovered that so-called disproportionation reactions may occur simultaneously with the CO2 reduction reaction influencing the product spectrum. Moreover, we focused on metalloprotoporphyrins immobilized on a graphite surface. We found that the selectivity can be steered toward formic acid with rhodium, tin or indium metal centers. Apart from intrinsic catalyst parameters, we studied the influence of parameters related to the immobilization and the composition of the electrolyte. We showed that the substrate and its pretreatment as well as encapsulation of the catalyst in polymers can have a signifcant influence on the electrocatalysis of CO2 reduction. The results obtained in this thesis provide insight in the energy efficiency, reaction rate and selectivity of the CO2 reduction reaction, and play an important role for the development of an industrially viable process. Show less
In this thesis we have discussed several parameters that affect the electrochemical conversion of enviromentaly harmful molecules such as nitrates and carbon dioxide to more valuable and less... Show moreIn this thesis we have discussed several parameters that affect the electrochemical conversion of enviromentaly harmful molecules such as nitrates and carbon dioxide to more valuable and less deleterious compounds, in order to cast light onto the mechanism of the reaction to achieve an efficient and selective system.The thesis is divided in two main parts, the reduction of nitrates(chapter 2) and the mechanistic study of CO2 conversion to different products such as ethanol(chapter 3), ethylene(chapters 4 and 5) and propylene carbonate (chapter 6). Show less
This thesis is part of NanoNextNL, a micro and nanotechnology innovation consortium of the Government of the Netherlands and 130 partners from academia and industry. More information on www... Show moreThis thesis is part of NanoNextNL, a micro and nanotechnology innovation consortium of the Government of the Netherlands and 130 partners from academia and industry. More information on www.nanonextnl.nl. Show less