Commissariat à l'Énergie Atomique
Job title:
Thermodynamic Modelling of Protective Coating for Solid Oxide Electrolysis Cells H/F
Company:
Commissariat à l’Énergie Atomique
Job description
Organisation The French Alternative Energies and Atomic Energy Commission (CEA) is a key player in research, development and innovation in four main areas :
- defence and security,
- nuclear energy (fission and fusion),
- technological research for industry,
- fundamental research in the physical sciences and life sciences.
Drawing on its widely acknowledged expertise, and thanks to its 16000 technicians, engineers, researchers and staff, the CEA actively participates in collaborative projects with a large number of academic and industrial partners.The CEA is established in ten centers spread throughout FranceReference 2024-33846Position descriptionCategoryMaterials, solid state physicsContractPostdocJob titleThermodynamic Modelling of Protective Coating for Solid Oxide Electrolysis Cells H/FSubjectSolid oxide electrolysis cells are a highly promising technology for producing hydrogen by electrolysis of water at high temperature. While high operating temperature offers many benefits, it can lead to degradation of the interconnectors. Coatings are proposed to improve the long-term performance of interconnectors. Here, the aim is to find the best coating candidates. In this context, you will join the LM2T team within the DIADEM Project: https://www.pepr-diadem.fr/projet/atherm_coat-en/Contract duration (months)24Job descriptionIn the pursuit of a sustainable energy future, solid oxide electrolysis cells (SOECs) are a highly promising technology for producing clean hydrogen by electrolysis of water at high temperature (between 500 and 850°C). Although high operating temperature offers many benefits (higher efficiency and lower power consumption), it can lead to degradation of the interconnectors. Coatings are proposed to improve the long-term performance of interconnectors and reduce corrosion problems, such as (i) development of passivation layers that increase electrical resistivity of the interconnector and (ii) formation of volatile species that poison the O2 electrode. The aim is to find the best coating candidates with high thermodynamic stability, high electrical conductivity and low cation diffusivity. In this context, you will join the LM2T team within the DIADEM Project (https://www.pepr-diadem.fr/projet/atherm_coat-en/) for innovative materials.Your role will be to:1) Perform thermodynamic simulations using CALPHAD method and Thermo-Calc Software to predict the stability range of a set of coating candidates (e.g. spinel oxides and perovskites) and the possible decomposition reactions in different atmosphere conditions (temperature and oxygen partial pressure). In this step, the candidate will also perform a critical review of the thermodynamic data available in the literature.2) To couple information obtained from CALPHAD calculations and the thermodynamic database (e.g. volume and cation disorder) to estimate the thermal expansion and electrical conductivity (simplified by percolation theory) of the most promising compositions.The candidate will work closely with the experimental team (ISAS/LECNA and UMR-IPV) producing the coatings to guide future trials and adapt the method to better meet large-scale production needs.Skills/Qualifications:– PhD degree in Chemistry, Physics, Chemical Engineering, Materials Engineering or related fields.-You have strong background in thermodynamics.-Experience with method CALPHAD and Thermo-Calc is expected, programming skills are essential.– Experience in the field of solid oxide electrolysis cell and coatings is an asset.Position locationSiteSaclayJob locationFrance, Ile-de-France, Essonne (91)LocationGif-sur-YvetteRequesterPosition start date28/10/2024
Expected salary
Location
Essonne
Job date
Thu, 24 Oct 2024 03:44:34 GMT
To help us track our recruitment effort, please indicate in your email/cover letter where (vacanciesineu.com) you saw this job posting.