ICMCTF2009 Session G5/H5: Coatings for Renewable Energy Systems
Time Period MoA Sessions | Abstract Timeline | Topic G Sessions | Time Periods | Topics | ICMCTF2009 Schedule
Start | Invited? | Item |
---|---|---|
1:30 PM | Invited |
G5/H5-1 Electrochemical Energy Conversion: Coatings for Fuel Cells, Electrolysers and Batteries
E. Roberts (Unversity of Manchester, United Kingdom) Electrochemical energy conversion devices include state of the art energy storage systems such as lithium-ion batteries, electrolysers such as those used in the chlor-alkali industry, and fuel cells which could offer a clean alternative to the internal combustion engine for transport. The environment in electrochemical energy conversion devices is typically highly corrosive. Strongly oxidising species are normally present in the electrolytes and high positive potentials can occur at the electrodes. Corrosion of materials in electrochemical devices often leads to a rapid deterioration in performance, severely limiting the lifetime. At the same time, electrode materials are required to provide high conductivity, low contact resistance and in some cases electrocatalytic activity. In addition, material costs can make a significant difference to the commercial viability of these devices. This is particularly true for fuel cell systems, where material costs will need to be significantly reduced compared to the current state of the art if this technology is to make a significant impact. Coated materials may provide a practical solution, where a low cost substrate is coated with thin layer of a material which offers the required surface properties. In this paper, the nature of electrochemical energy conversion devices will be reviewed, and the desired properties of materials, particularly the plate materials, will be identified. Methods for characterising material performance and performance targets will be considered in this context. The types of coatings that have been studied will be discussed and there performance will be evaluated. Coatings used in this context include conducting polymers, amorphous and diamond-like carbon, as well as ultra-thin noble metal coatings. Finally, the future directions and opportunities in this field will be considered. |
2:10 PM | Invited |
G5/H5-3 Thin-Film Based Superconducting Wires for Electric Power Applications
V. Selvamanickam (University of Houston) High Temperature Superconductors (HTS) have been developed over the last 20 years for electric power applications. The challenge was in fabricating oxide ceramic material in form of flexible wires in continuous lengths of more than a kilometer with a high current carrying capability. This goal was recently met by SuperPower Inc and a prototype power transmission cable made with nearly 10,000 meters of HTS wire was installed and energized in the electric power grid. The enabling technology for this achievement is ion beam assisted deposition (IBAD) which provides the ability to grow nearly single-crystalline films on thin tapes of polycrystalline substrates such as nickel superalloys. A high degree of biaxial texture is developed in IBAD MgO within a thickness of 10 nm. This texture is epitaxially transferred to a superconducting film via one or two intermediate layers. Metal Organic Chemical Vapor Deposition (MOCVD) is used to epitaxially grow high quality REBa2Cu3O7 (RE = rare earth) superconducting films with a current density over 6 MA/cm2. Multiple buffer layers based on bixbyite, rock salt, and perovskite crystal structures as well as amorphous layers all with a total thickness less than 200 nm are deposited between the flexible metal substrate and the superconducting layer for the purpose of diffusion barrier, nucleation promoter, and lattice match. In addition to near-single crystalline growth of the superconductor, high performance is also achieved through nano-scale defect structure for pinning of fluxons. The ability to grow near-single crystalline films on inexpensive polycrystalline substrates has been the key to success with HTS and now this technique is being explored for other energy applications too. |
2:50 PM |
G5/H5-5 Deposition and Characterisation of NiOx Films by Reactive Sputtering for Application in Dye Sensitized Solar Cells
M. Awais, M. Rahman, D. MacElroy (University College Dublin, Ireland); N. Coburn, D. Dini, J.G. Vos (Dublin City University, Ireland); D.P. Dowling (University College Dublin, Ireland) NiOx due to its high band gap (3.8 eV) and p-type nature has considerable potential for use as an electrode in a tandem dye-sensitized solar cells (DSSc)1. However to-date the efficiency of sol gel deposited NiOx semiconductors in DSSc has been found to be relatively poor2, which limits the effectiveness of the tandem cells. One of the possible ways to improve this efficiency is to deposit the coating by the reactive sputtering method. This is because the uniformity, reproducibility, and mechanical durability of the sputtered deposited film is much higher compared to sol-gel or other wet chemical deposition techniques. In this study, NiOx films were deposited using the unbalanced magnetron sputtering technique. The coating was deposited onto both silicon wafer and indium tin oxide glass (ITO) substrates. The influence of deposition parameters such as pressure, nickel target current and substrate bias voltage were correlated with coating properties, including surface roughness, thickness, crystallographic structure and surface energy. These evaluations were carried out using optical profilometry, spectroscopic ellipsometry, XRD and water contact angle measurements. The NiOx coatings were sensitized with Ru-complex dye containing appropriate anchoring moieties (carboxylic group). The dye adsorption was investigated in transmission mode on the ITO using UV-Vis spectroscopy in the range 200 – 600 nm. Dye adsorption was enhanced on nickel oxide surfaces exhibiting higher surface energy values. For example for 70 nm thick NiOx coatings, it was found that increasing surface roughness (Ra) from 4.0 to 4.4 nm, with corresponding increase in surface energy from 37.1 to 57.6 mN/mm, there was a 12 % increase in the level of light absorption. 1E. L. Miller, R. E. Rocheleau, Journal of Electrochemical Society 144 (1997) 1995. 2J. He, H. Lindström, A. Hagfeldt, S. Lindquist, Journal of Physical Chemistry B 103 (1999) 8940. |
|
3:10 PM | Invited |
G5/H5-6 Renewable Energy Systems - What Coatings Do We Need?
H. Bernhoff, M. Bergkvist, (Uppsala University, Sweden) Rapid developments in different renewable energy systems bring about an increased need for functional and specific-purpose coatings. Three main categories of renewable energy systems can be recognized : (1) water power systems including wave power, marine current, tidal systems, and conventional hydro power installations (2) wind power systems, and (3) solar and solar-thermal systems. Furthermore, several additional thermal systems utilizing geothermal energy, ocean thermal energy, recycling of heat or cooling energy have additional demands on coatings. Important driving factors for new coatings and coating applications in these systems are their power efficiencies, lifetimes and environmental considerations concerning greases, lubricants and solid lubricants, to improve properties like friction, wear, noise, etc. The terminological requirements apply in systems with movable parts. For example there are often elastomer parts moving against a metal counter body requiring surface modification of materials and wear resistant coatings at long sliding distances. Polymeric and composite coatings could be used for this purpose. A special category of corrosion resistant and wear resistant coatings is required in systems for offshore systems such as wind and wave-power installation. Submerged component will also need environmental friendly antifouling systems. Furthermore hydrophobic coatings on wind-turbine blades can be applied to reduce forming of ice and aggregation of contaminants which will affect aerodynamic performance. In this paper several renewable energy systems will be described and the most important parts requiring coating applications with specific parameters will be discussed. |