Search results for "MOCVD"
showing 8 items of 28 documents
Evaluation of Haynes230 for Solid Oxide Fuel Cell Interconnect Application
2008
National audience; Abstract - Interconnects are among the most critical parts for commercialization of SOFCs. They separate the fuel and oxidant gases and provide electric connection between the anode and cathode of adjacent cells. A Ni-based alloy, Haynes230 alloy, was evaluated in this work as a candidate material for SOFC interconnects application. During operation, a scale of chromia forms on Haynes230. Unfortunately, this scale can degrade the fuel cell performances. Thus, protective coatings are required to increase long-term stability. In this study, a nanometric layer made of reactive element oxide (La2O3, Nd2O3 and Y2O3) was applied on alloy surface by MOCVD. Perovskite oxides, suc…
Résistance à la corrosion d'interconnecteurs métalliques de piles à combustibles de type SOFC : Influence de la vapeur d'eau
2008
Les interconnecteurs représentent une pièce maîtresse des piles à combustibles à oxyde solide (Solid Oxide Fuel Cells : SOFCs) car ils sont chargés de collecter et de délivrer le courant produit par la pile. Les matériaux d'interconnecteurs sont à la fois en contact avec l'anode et la cathode et doivent donc être parfaitement stables dans l'air (côté cathodique) et dans l'hydrogène enrichie en vapeur d'eau (côté anodique). Les matériaux métalliques les plus prometteurs sont les chromino-formeurs. Ces alliages sont choisis car, à haute température, ils forment une couche de chromine, Cr2O3, protectrice vis-à-vis des conditions corrosives de fonctionnement de la pile. Cependant, cette couche …
INTERCONNECTEURS METALLIQUES DE PILES A COMBUSTIBLES DE TYPE SOFC : EFFET DE LA VAPEUR D'EAU SUR LA RESISTANCE A LA CORROSION
2008
Les interconnecteurs représentent une pièce maîtresse des piles à combustibles à oxyde solide (Solid Oxide Fuel Cells : SOFCs) car ils sont chargés de collecter et de délivrer le courant produit par la pile. Les matériaux d'interconnecteurs sont à la fois en contact avec l'anode et la cathode et doivent donc être parfaitement stables dans l'air (côté cathodique) et dans l'hydrogène enrichie en vapeur d'eau (côté anodique). Les matériaux métalliques les plus prometteurs sont les chromino-formeurs. Ces alliages sont choisis car, à haute température, ils forment une couche de chromine, Cr2O3, protectrice vis-à-vis des conditions corrosives de fonctionnement de la pile. Cependant, cette couche …
Metallic interconnects for SOFC: effect of water vapour on oxidation resistance of differently coated alloys.
2008
The need of interconnect to separate fuel and oxidant gasses and connect individual cells into electrical series in a SOFC stack appears as one of the most important point in fuel cell technology. Due to their high electrical and thermal conductivities, thermal expansion compatibility with the other cell components and low cost, Ferritic Stainless Steels (FSS) are now considered to be among the most promising candidate materials as interconnects in SOFC stacks. Despite the formation at 800°C of a protective chromia Cr2O3 scale, it can transform in presence of water vapour in volatile chromium species leading to the lost of its protectiveness and then the degradation of the fuel cell. A prev…
Interconnecteurs métalliques de piles à combustible de type SOFC - Résistance à la corrosion et conductivité électrique à haute température
2009
The need of interconnect to connect individual cells into electrical series in a SOFC stack appears as one of the most important point in fuel cell technology. The main important criteria requires for interconnect is an excellent oxidation resistance in air and in H2/H2O. The goal of this study is to determine the influence on corrosion behaviour of a reactive element oxide coating (La2O3, Y2O3) realized by MOCVD on different metallic alloys like Crofer22APU, Haynes230 and Fe30Cr. The realisation of long ageing (7 700 and 15 400 hours) proved to be insightful. The corrosion kinetic experiments, the oxide scale characterisation and ASR measurements established that the presence of perovskite…
Initial stages of metal oxides thin films growth by MOCVD: physicochemical characterisation of the film/substrate interface
2006
The initial stages of Metalorganic Chemical Vapour Deposition (MOCVD) of TiO2 thin films on Si(100) were studied in situ by surface analyses (XPS, ARXPS, AES). An original experimental set-up was built for this purpose and developed. Information obtained from these in situ experiments was completed by ex situ characterisations (HRTEM, SIMS, GIXRD...).The formation of an interfacial SiOy<2 layer resulting of the interaction of the precursor Ti(OCH(CH3)2)4 with the substrate takes place before the formation of stoichiometric TiO2 and leads to the presence of carbon at the interface. At the deposition temperature, 675 °C, silicon diffusion within the TiO2 external layer was also revealed. Conc…
Study of TiO2 nanostructures grown in a MOCVD reactor in presence of metallic catalysts. Valorization of these TiO2 nanostructures
2017
Within the Nanoform Theme, Ax Nanosciences, ICB, we realize the growth of 1D, 2D and 3D hybrid nanostructures based on TiO2 by MOCVD. Our work deals with the theoretical aspect of the formation of these nanostructures (growth and kinetic models, structure and texture) and the study of photoelectric, optical and physicochemical properties as well as the development of applications of these structures in physics (random laser), photocatalysis, energy (solar cells). Under certain perfectly controlled conditions, we obtain original TiO2 structures not yet described in the literature: membranes, rods , canals, crucibles, COHN (COaxiales Heterostructures Nanowires). Our previous work made it poss…
The Effect of a Nucleation Layer on Morphology and Grain Size in MOCVD-Grown β-Ga2O3 Thin Films on C-Plane Sapphire
2022
This research is funded by the Latvian Council of Science project “Epitaxial Ga2O3 thin films as ultrawide bandgap topological transparent electrodes for ultraviolet optoelectronics” No. lzp-2020/1-0345. S.O. was supported by the European Union’s Horizon 2020 program, under Grant Agreement No. 856705 (ERA Chair “MATTER”). Institute of Solid State Physics, University of Latvia as the Center of Excellence has received funding from the European Union’s Horizon 2020 Framework Programme H2020-WIDESPREAD-01-2016-2017-TeamingPhase2 under grant agreement No. 739508, project CAMART².