Metal oxide nanomaterials and their application in solar photoelectrolysis of water

Solar generated hydrogen as an energy source is green, sustainable, with a high energy density. One day the majority of current fossil fuel based technology could be replaced with hydrogen technology reducing CO2 emission drastically. The goal in this research is to explore hybrid metal oxide photocatalysts in the pursuit of achieving highly efficient photoanodes for use in photoelectrochemical cells (PEC). Achieving high efficiencies of hydrogen production in photoelectrochemical cells is the key challenge for the commercialisation of PEC technology as a viable, sustainable, hydrogen source; limited only by the lifetime of the sun and the resources of the metal oxide materials. In this research TiO2, Fe-Ti-O, ZnO, and Zn2TiO4 are the photocatalysts explored. Alloys of Ti-Fe-O showed improvement over TiO2, whilst a hybrid heterostructure of ZnO/Zn2TiO4/TiO2 enhanced photocurrent densities significantly. A barrier layer in the photoanode achieved localised exciton separation and reduction of recombination rates by inhibiting back flow of electrons after injection into the TiO2 layer. Nanotubes are created by the simple electrochemical process of anodisation. The nanotube composition depends on the anode material. To control the composition ofthe anode, iron and titanium are co-deposited onto a substrate using electron beam evaporation. The introduction of iron into titania nanotubes engineered the band gap, lowering the band gap energy to that of iron oxide whilst the positions of the conduction and valence bands with respect to the oxidation and reduction potentials of water remained favourable. Fe-Ti-O nanotubes showed remarkable photocurrent density improvement compared to TiO2 nanotubes. ZnO nanostructures deposited by vapour transport mechanisms showed variability in the morphology of the structures, as governed by the growth dynamics. Herein, it is shown that an electronically favourable situation arises by the formation of a ZnO-Zn2TiO4-TiO2 heterostructure and a high photocatalytic activity is reported. The structure is composed of a large surface area ZnO nanorod photoabsorber formed on a Ti foil which forms a Zn2TiO4 barrier layer between ZnO and TiO2. The Zn2TiO4 layer inhibits electron transport toward the surface of the photoanode whilst encouraging charge transport to the hydrogenation electrode. The heterostructure interfacial surface area is extended through the utilisation of TiO2 nanotubes, which demonstrated a 20.22 % photoelectrochemical efficiency under UV illumination. Surface modification of ZnO nanorods with aerosol assisted chemical vapour deposited TiO2 nanoparticles enhanced photocurrent densities of the ZnO rods, improving charge separation of excitons created within the TiO2 nanoparticles. ZnO nanotubes formed via a novel route using chemical bath deposition of ZnO is investigated, an annulus ZnO seed layer facilitated the site specific growth of ZnO nanotubes whilst a uniform seed layer formed ZnO nanorods

Global Trends & Challenges in Water Science, Research and Management

The global water challenge is unprecedented. Climate change, rapid urbanisation, increasing consumption and demand for food and energy, and changing land use, will leave few countries and communities unaffected. The demand for water and sanitation services is greater than it has ever been, and water has never been higher on the agenda. The Sustainable Development Goals (SDGs) not only provide a framework to address water challenges, they put water at the centre of the global agenda on sustainable development. This presents opportunities for the water sector to develop innovative solutions and scale-up best practice. Water management is a complex multi-disciplinary topic, and water professionals come in many different shapes. One of the unique strengths of IWA is bringing together experts from across the globe and specialisations into communities of practice, IWA’s Specialist Groups. Connecting people from across disciplines and across national boundaries accelerates the science, innovation and practice that can make a difference in addressing water challenges and pushes the sustainability agenda. The Global Trends and Challenges in Water Science, Research and Management compendium draws upon the expertise of IWA’s specialist groups who have identified the hot topics, innovations and global trends in water science, research and management that will have impact in solving global water challenges. The compendium highlights a diversity of approaches, from detailed technical and scientific aspects to more integrated approaches

Production of Biofuels and Numerical Modeling of Chemical Combustion Systems

Biofuels have recently attracted a lot of attention, mainly as alternative fuels for applications in energy generation and transportation. The utilization of biofuels in such controlled combustion processes has the great advantage of not depleting the limited resources of fossil fuels while leading to emissions of greenhouse gases and smoke particles similar to those of fossil fuels. On the other hand, a vast amount of biofuels are subjected to combustion in small-scale processes, such as for heating and cooking in residential dwellings, as well as in agricultural operations, such as crop residue removal and land clearing. In addition, large amounts of biomass are consumed annually during forest and savanna fires in many parts of the world. These types of burning processes are typically uncontrolled and unregulated. Consequently, the emissions from these processes may be larger compared to industrial-type operations. Aside from direct effects on human health, especially due to a sizeable fraction of the smoke emissions remaining inside residential homes, the smoke particles and gases released from uncontrolled biofuel combustion impose significant effects on the regional and global climate. Estimates have shown the majority of carbonaceous airborne particulate matter to be derived from the combustion of biofuels and biomass. “Production of Biofuels and Numerical Modelling of Chemical Combustion Systems” comprehensively overviews and includes in-depth technical research papers addressing recent progress in biofuel production and combustion processes. To be specific, this book contains sixteen high-quality studies (fifteen research papers and one review paper) addressing techniques and methods for bioenergy and biofuel production as well as challenges in the broad area of process modelling and control in combustion processes

Proceedings of the 10th International Chemical and Biological Engineering Conference - CHEMPOR 2008

This volume contains full papers presented at the 10th International Chemical and Biological Engineering Conference - CHEMPOR 2008, held in Braga, Portugal, between September 4th and 6th, 2008.FC