Offers “CEA”

Expires soon CEA

Thermodynamic Modelling of Complex Oxides for Smart Sensors H/F

  • Gif-sur-Yvette (Essonne)
  • IT development

Job description

Détail de l'offre

Informations générales

Entité de rattachement

Le CEA est un acteur majeur de la recherche, au service des citoyens, de l'économie et de l'Etat.

Il apporte des solutions concrètes à leurs besoins dans quatre domaines principaux : transition énergétique, transition numérique, technologies pour la médecine du futur, défense et sécurité sur un socle de recherche fondamentale. Le CEA s'engage depuis plus de 75 ans au service de la souveraineté scientifique, technologique et industrielle de la France et de l'Europe pour un présent et un avenir mieux maîtrisés et plus sûrs.

Implanté au cœur des territoires équipés de très grandes infrastructures de recherche, le CEA dispose d'un large éventail de partenaires académiques et industriels en France, en Europe et à l'international.

Les 20 000 collaboratrices et collaborateurs du CEA partagent trois valeurs fondamentales :

• La conscience des responsabilités
• La coopération
• La curiosité

Référence

2024-33847

Description du poste

Domaine

Matériaux, physique du solide

Contrat

Post-doctorat

Intitulé de l'offre

Thermodynamic Modelling of Complex Oxides for Smart Sensors H/F

Sujet de stage

The Hiway-2-mat project aims to accelerate the discovery of materials for smart sensors using high-throughput combinatorial approaches and autonomous configurations to explore complex oxide compositions. In this context, the CALPHAD method is a valuable tool for calculating phase diagrams, either to better prepare experiments or guide the autonomous robot in real-time, providing crucial data for on-the-fly characterization and enhancing material exploration.

Durée du contrat (en mois)

12

Description de l'offre

The search for more efficient materials follows a pattern that has changed very little over the years, involving poorly automated phases of synthesis, characterization and measurement of functional properties. This pattern has proved its strength in creating knowledge bases and, in some cases, leading to the discovery of promising formulations. However, this classic approach remains ineffective because it is time-consuming and generally covers a reduced range of compositions.

The project Hiway-2-mat seeks to use high-throughput combinatorial approaches and develop autonomous configurations to explore the compositional spaces of complex oxide materials, with the aim of accelerating the discovery of materials for smart windows, smart sensors, low power lighting and electronic systems. In this context, CALPHAD method appears to be a valuable tool before or during materials exploration, as it can provide a number of useful insights into the role of oxidation state or oxygen partial pressure on phase stability, and on the degree of substitution of doping elements in an oxide matrix.

The aim is to calculate phase diagrams of complex oxides, based on available databases, either to better prepare combinatorial experiments, or to drive the autonomous robot on the fly, providing additional information for on-line characterization.

In this context, you will join the LM2T team within the DIADEM Project Hiway-2-mat (https://www.pepr-diadem.fr/projet/hiway-2-mat/) 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 complex oxides (i.e. (Ba/Ca/Sr)(Ti/Zr/Sn/Hf)O3, doped VO2 or ZrO2-HfO2-CeO2-SnO2) 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) Develop a rapid screening method to search for the most promising compositions.

3) Perform thermodynamic modelling assessment of most promising compositions not yet include in the available databases.

The candidate will work closely with the experimental platform development team 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 Thermocalc is expected, programming skills are essential.

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