1. Seksjon for Faststoff-elektrokjemi (FASE) Section for Solid-state electrochemistry Truls Norby & Reidar Haugsrud FASE Research group at Department of Chemistry FERMiO Functional Energy Related Materials in Oslo Top-tier group at SMN/MN faculty SMNCentre for Materials Science and Nanotechnology Centre at the MN faculty

2. Section for Solid-State Electrochemistry (FASE) Our research in solid-state electrochemistry has elements of ◦ Inorganic chemistry ◦ Physical chemistry ◦ Materials chemistry ◦ Nanotechnology ◦ Computational materials science Typical applications of our research comprise ◦ Clean and efficient energy conversion technologies  Renewable energy harvesting and storage  Hydrogen technologies  Carbon capture and better uses of fossil fuels  Catalysis and photocatalysis ◦ Materials synthesis, fabrication, use, and degradation/corrosion

3. FASE Professor Truls Norby Assoc. professor Reidar Haugsrud 1 technical 1 administrator 6 post-docs 12 PhD-students 6 Master-students Visiting researchers Exchange, project, and internship students Total ca 30 Located in Oslo Innovation Centre (Forskningsparken)

4. FASE Technologies Functional energy related materials CO 2 -free fossil energy ◦ Gas separation membranes ◦ Fuel cells Hydrogen technology ◦ Fuel cells ◦ Steam electrolysis ◦ Photo-electrochemical splitting of water High temperature corrosion Sensors for extreme conditions ◦ High temperature, corrosive environments, Space, Nuclear power, Energy processes Clean water and air – photocatalysis Thermoelectric materials ◦ Solar and waste heat utilisation

5. FASE Science Defects in crystals ◦ Defect chemistry ◦ Transport ◦ Emphasis on oxides and hydrogen Solid state reactions Electrode reactions Relation between structure, composition, and functional properties Design, make, characterize, and model new materials Questions: ◦ H + in oxides? H in oxides? H - in oxides? ◦ N 3- in oxides? ◦ Cation diffusion in oxides? Lifetime of devices? ◦ Novel solid-state proton conductors? ◦ Charge transfer mechanisms in electrodes? ◦ Why do grain boundaries behave so differently? ◦ How does a photocatalyst work?

6. 6 FASE Methods Synthesis Sample preparation Structure: XRD Microstructure: SEM Measurements of concentration and transport of defects –Thermogravimetry –Reaction rates –Diffusion –Permeability –Electrical properties Electrochemical studies –Fuel cell tests –Electrode kinetics –Photoelectrochemistry Further characterization, often in collaboration: –TEM, XPS, SIMS, ND… Computational simulations of structure and defects

7. Examples of current FASE project possibilities Pulsed Laser Deposited (PLD) films for fuel cells, electrolysers, and gas separation membranes Proton conducting oxides for fuel cells and electrolysers; measurements and computational approaches Electrodes for H + -conducting fuel cells and electroysers New proton-electron mixed conductors for gas separation membranes Water splitting or CO 2 -to-fuel generation by solid-state photoelectrochemistry Pure water by photocatalysis – is it possible? Thermoelectric oxides – from heat to electricity Grain boundaries and interfaces; TEM and properties Diffusion and surface kinetics – use of isotopes and ToF-SIMS Nitrogen defects in oxides Combined computational and experimental studies and more; depends on what is hot when you start, and your interests…

8. Where do FASE MSc and PhD students go?

9. Science in focus …. but not only…

10. Take your Master of Science in FASE! Chemistry ◦ Materials chemistry ◦ Inorganic chemistry ◦ Physical chemistry MENA ◦ Materials, energy and nanotechnology Requirements ◦ KJM or MENA bachelor or similar Recommended courses ◦ None in particular Supervisors: ◦ Truls Norbytruls.norby@kjemi.uio.no22840654 99257611 ◦ Reidar Haugsrud reidar.haugsrud@smn.uio.no22840659 ◦ + one PhD or post-doc co-supervisor