POST-DOC POSITION IN THE FIELD OF
“Hybrid nanoarchitectures for renewable energy applications”
The Regional Centre of Advanced Technologies and Materials (RCPTM; www.rcptm.com
) at Palacký University in Olomouc, Czech Republic, and the Institute for Surface Science and Corrosion at Friedrich-Alexander University, Erlangen, Germany (LKO, http://www.lko.uni-erlangen.de
) announce the opening of a new postdoc position for scientists experienced in the fields of physics, plasma chemistry, materials science, and nanomaterials.
The successful candidate will receive a one-year contract (which would be extended up to five-years in the case of positive annual evaluation) at Palacký University in Olomouc in the Czech Republic. As a part of the contract it is expected to spend extended visits at research group at LKO, Friedrich-Alexander University. This unique position is open immediately for qualified applicants. The expected beginning of the contract: January 1st.
The research program:
The research work of the photoelectrochemical group at RCPTM in Olomouc under the supervision of Prof. Schmuki is focused on the development, characterization, and testing the functional properties of advanced nano-heterostructures based on TiO2, Fe2O3, WO3, etc. combined with various hybrid counterparts (co-catalysts, multilayer assemblies, optical sensitization, etc.) for hydrogen generation via the solar water splitting.
The inorganic materials are primarily synthetized by state-of-the-art plasma-assisted deposition techniques involving high-power impulse magnetron sputtering (HiPIMS) and plasma enhanced chemical vapor deposition (PECVD) methods as well as chemical pathways such as hydrothermal growth, spray pyrolysis, doctor blading, etc.
Required experiences in some of these areas:
• Pulse modulated (DC and/or RF, MF) reactive magnetron sputtering of nanocrystalline thin films and nanostructures (pure metals, metal alloys, oxides, nitrides, etc.);
• Experience with the high-power impulse magnetron sputtering (HiPIMS).
• Utilization of multi magnetron deposition sources (three or more magnetron guns), DC/RF Bias, etc.;
• Basic and advanced deposition plasma diagnostics (optical emission spectroscopy, Langmuir probes, absorption spectroscopy, etc.);
• Understanding of advanced methods and results of nanomaterials characterization (HRTEM, TEM, XPS, XRD, Raman spectroscopy, EPR, GI-XRD);
The applicant responsibilities:
• Controlled deposition of inorganic nanostructured materials (mainly TiO2; α-Fe2O3, WO3, BiVO4, etc.) by aforementioned plasmatic systems.
• Controlled deposition of thick (up to 10 µm) pure metal (Ti, W, Fe, Zn, Al, etc.) and metal alloys (Ti-Pt, Fe-Ti, Ti-Nb-Ta, etc.) onto various substrates (FTO, glass, metals, etc.) as the starting materials to growth nanostructures by electrochemical anodization;
• Controlled deposition of multilayers structures, over-coatings of various nanostructures (nanotubes, nanorods, etc.), preparation of gradient heterojunctions, etc.;
• Deposition plasma diagnostics to correlate the plasma conditions with the films’ physical and functional properties as well as to ensure the process reproducibility
• S. Kment, P. Schmuki, Z. Hubicka, R. Zboril, et al., “Photoanodes with fully controllable texture: the enhanced water splitting efficiency of thin hematite films exhibiting solely (110) crystal orientation”, ACS NANO, 9 (20015) 7113-7123.
• S. Kment, P. Schmuki, E. Schubert, R. Zboril, “On the improvement of PEC activity of hematite thin films deposited by high-power pulsed magnetron sputtering method”, APPLIED CATALYSIS B: ENVIRONMENTAL, 165 (2015) 344-350.
• S. Kment, P. Schmuki, et al., “ High-power pulsed plasma deposition of hematite photoanodes for PEC water splitting”, CATALYSIS TODAY, 230 (2014) 8-14.
• J. Tucek, K. C. Kemp, K. S. Kim, R. Zboril, “Iron-oxide-supported nanocarbon in lithium-ion batteries, medical, catalytic and environmental applications”, ACS NANO, 8 (2014) 7571-7612.
• K. Sivula, R. Zboril, F. Le Formal, R. Rosa, A. Weidenkaff, J. Tucek, J. Frydrych, M. Graetzel, “Photoelectrochemical water splitting with mesoporous hematite prepared by a solution-based colloidal approach”, JOURNAL OF THE AMERICAN CHEMICAL SOCIETY, 132 (2010) 7436-7444.
• I. Cesar, K. Sivula, A. kay, R. Zboril, M. Graetzel, “Influence of feature size, film thickness, and silicon doping on the performance of nanostructures hematite photoanodes for solar water splitting”, JOURNAL OF PHYSICAL CHEMISTRY C, 113 (2009) 772-782.
• J. Frydrych, L. Machala, J. Tucek, K. Siskova, J. Filip, J. Pechousek, K. Safarova, M. Vondracek, J. H. Seo, O. Schneeweiss, M. Graetzel, K. Sivula, R. Zboril, “Facile fabrication of tin-doped hematite photoelectrodes – effect of doping on magnetic properties and performance for light-induced water splitting”, JOURNAL OF MATERIALS CHEMISTRY, 22 (2012) 23232-23239.
• K. Lee, A. Mazare, P. Schmuki, “One-dimensional titanium dioxide nanomaterials: nanotubes”, CHEMICAL REVIEWS, 114 (2014)
We offer a stimulating environment, attractive salary, and a unique opportunity to join two well-known research groups with state of the art instrumentation including plasma-assisted deposition methods (hi-tech 5-magnetron-guns HiPIMS system, PECVD), cryoHRTEM, AFM, STM, SEM, SQUID, PPMS, XPS and advanced Raman spectroscopy, GDOES, in-field Mössbauer spectroscopy, NMR, fluorescence spectroscopy, and one of the best equipped electrochemical and photoelectrochemical laboratory in Europe.
PhD or equivalent in the field of plasma deposition; good publication record, excellent oral and written English.
Physics, Plasma deposition, Plasma chemistry, Solid state physics
Experienced researcher (4-10 yrs). Post-Doc or Senior Researcher
Recognized Researcher (R2)
Comment/web site for additional job details
Submit an application including a curriculum vitae and a list of publications to: firstname.lastname@example.org
, and email@example.com
. Arrange for a letter of recommendation to be sent directly to the same email addresses.
Screening of applicants will resume immediately. Selected applicants will be invited for an interview.