The overall aim of the project is to develop high performance electrodes that are easy to synthesize, safe, non-toxic, long-lasting and cheap in order to achieve a fully functional and ready to use sodium-ion battery (aqueous and organic electrolytes) targeted specifically for large-scale stationary storage, at ambient temperature.
Description
Sodium-ion batteries for large-scale energy storage
World-wide implementation of renewable energy sources (solar, wind and tidal) is substantially dependent on the availability of improved technologies for the production of efficient and inexpensive stationary energy storage systems. The extension of battery technology to large-scale applications has become a global priority as intermittent renewable energy systems need to be integrated in the electrical grid. Rechargeable Na-ion batteries have recently re-emerged as promising systems for large-scale stationary energy storage. The fundamental principles of sodium-ion are identical to those of lithium-ion batteries: in charge and discharge the alkali ions shuttle between the two electrodes. However, the use of sodium has a number of advantages due to its unlimited sources, ease of recovery and lower price.
The overall aim of the project is to develop high performance electrodes that are easy to synthesize, safe, non-toxic, long-lasting and cheap in order to achieve a fully functional and ready to use sodium-ion battery (aqueous and organic electrolytes) targeted specifically for large-scale stationary storage, at ambient temperature. The project will use state-of-the-art characterisation techniques to investigate the structural/microstructural development of anode/cathode materials to guide the design of the best performing combination of electrode/electrolytes assemblies for sodium-ion battery technology. The project will provide a broad training in materials chemistry and engineering. It will involve synthetic and manufacturing work coupled with prototype development. Furthermore, it will give the opportunity to visit and work at international laboratories and synchrotron X-ray/neutron sources worldwide. The project will involve interactions with both academic and industrial groups.
Swansea University's College of Engineering provides a fantastic study environment for postgraduate students.
Our brand new Bay Campus (opening 1st September 2015) has a fantastic beachfront location near to Swansea City Centre and Marina.
This scholarship is funded by, and is part of, The National Research Network in Advanced Engineering and Materials (AEM), which is a transformative alliance that will enhance fundamental and applied research in Wales: www.ernw.ac.uk
Eligibility
We are looking for qualified candidates that are imaginative, driven and ambitious. Applicants should hold or be completing an undergraduate honours degree with a 1st or a 2.1 classification.
Degrees in all areas of chemistry (especially electrochemistry), materials science, engineering, and other related subjects will be considered.
UK/EU and international students are welcome to apply, though only UK/EU fees are covered by this studentship. International students will be required to pay the difference between UK/EU and international fees.
Nr of positions available : 1
Research Fields
Engineering
Career Stage
Early stage researcher or 0-4 yrs (Post graduate)
Research Profiles
First Stage Researcher (R1)
Benefits
The studentship covers the full cost of UK/EU tuition fees, plus a tax free stipend of £14,562 p.a.
There will also be additional funds available for research expenses and conference attendance.