Cost-Effective Materials for The Energy Transition: From Water Splitting Catalysts to Carbon Dioxide Adsorbents

Identificador:  TDX:3839

Handle: https://hdl.handle.net/20.500.11797/TDX3839

Autores:  De Fez Febré, Mabel

Resumen:
The most plausible solution to satisfy the world’s energy demand following an environmentally friendly approach, is the use of renewable energies, such as the energy from the sun, solar energy, or the energy from the fermentation of organic matter under anaerobic conditions, biomass. On the one hand, the aim is the replacement of fossil fuels by carbon-free solar fuels, i.e., energy-rich chemicals formed with the help of sunlight. Artificial photosynthesis is implemented for this purpose. A strategy to store solar energy in chemical bonds (H2 and O2) and overcome the intermittency of this energy source. However, these storing systems have a bottleneck, the oxidation reaction of water to O2. Therefore, the search for a robust, efficient and inexpensive heterogeneous water oxidation catalyst is one of the greatest challenges that scientists are facing nowadays for the implementation of this energy-solving strategy as a commercial technology. This Thesis will develop the study of two different approaches to understand their contributions to the electrocatalytic properties of working anodes based on Earth abundant metals for the electrocatalytic water oxidation reaction in alkaline media. In Chapter 2, we will study the effect of doping on the electrocatalytic properties of hematite anodes doped with different concentrations of redox vs. non-redox active species (Ni and Zn). In Chapter 3, we will discuss the catalytic performance towards Oxygen Evolution Reaction in alkaline media of two series of spinel ferrites anodes: Ni1–xZnxFe2On and (Ni1–xZnx)2FeOn, analysing the effect of their controlled stoichiometry with variable Zn and Ni compositions. On the other hand, biomass, particularly biogas, could be another promising renewable energy due to the environmental benefit of using bio-methane as a substitute for fossil fuels. The bottleneck of this green fuel is the purification step, as biogas contains large quantities of CO2 that must be removed since they reduce its calorific value. For this reason, the development and implementation of effective carbon capture, utilization and storage (CCUS) technology is crucial. Thus, in Chapter 4 the objective will be to study our patented Metal-Organic Framework, TAMOF-1, as an adsorbent material for separation of carbon dioxide, methane and nitrogen mixtures by physisorption adsorption processes, comparing it with one of the most relevant commercial adsorbents, Cu-BTC. Finally, in Chapter 5 the range of application of this TAMOF-1 will be studied, extending its use to the separation of light hydrocarbons such as paraffin, olefin and alkyne gas mixtures, which are essential energy resources and raw materials for the production of several chemical products of high industrial importance.