Development of computational modeling tools for metallic materials for high-temperature aeronautics applications


Ref. num. AeroModelling_DT_RA01

Research support in Computational Modeling of Materials for Aeronautics

IMDEA Materials Institute is a public research organization founded in 2007 by Madrid’s regional government to carry out research of excellence in Material Science and Engineering by attracting talent from all over the world to work in an international and multidisciplinary environment. IMDEA Materials has grown rapidly since its foundation and currently includes more than 120 researchers from 22 nationalities and has become one of the leading research centers in materials in Europe which has received the María de Maeztu seal of excellence from the Spanish government. The research activities have been focused on the areas of materials for transport, energy, and health care and the Institute has state-of-the-art facilities for processing, characterization and simulation of advanced materials. More information can be found at


IMDEA Materials Institute has several openings for Research Support positions in Computational Modeling of Materials for Aeronautics.


The application is directed toward the development of next-generation metallic materials for high-temperature aeronautics engine applications via advanced manufacturing techniques (e.g. additive manufacturing of superalloys for turbine engine components). The objective of the projects is the development of the computational simulation tools that will enable a substantial step forward in the design and deployment of novel materials with desired microstructures, free of manufacturing defects, and hence with outstanding mechanical properties and superior lifetime at high temperatures.


The individual projects will focus on different aspects, including but not limited to: crystal plasticity modeling of the mechanical behavior of heterogeneous microstructure; modeling of fatigue and damage tolerance in heterogeneous microstructures; meshless (Lattice Boltzmann) simulations of fluid dynamics and phase transformations in various solidification processes (e.g. casting or additive manufacturing); etc.


Research and Development activities will be central to a large-scale collaborative project that is directly funded and coordinated by an international consortium from the aeronautics sector. As such, the project will be strongly applied and directed toward concrete problem-solving, while relying on state-of-the-art materials science, thermodynamics, and computational mechanics techniques. All tasks will be developed with the immediate objective of being implemented directly in the code used (and/or developed) by the industrial partner(s). Communication of research results will be regulated by strict confidentiality agreements, which may restrict the open publication in scientific journals.


The candidate will acquire hands-on experience with state-of-the-art modeling and simulation tools for materials science and engineering, in particular crystal plasticity, computational metallurgy, and/or computational fluid dynamics (LBM), as well as advanced training in computational mechanics, thermodynamics, and related materials science aspects, as well as a true application-oriented experience that will provide an outstanding expert profile for a career in the industrial sector.


The positions are most appropriate for recent graduate (or soon to graduate) in fields related to computational materials science, mechanical engineering, applied mathematics and modeling, computational thermodynamics, with interest in joining the private sector in the aeronautics industry, with a high probability of direct recruitment at the end of the project.


The candidate should have a degree in Mechanical Engineering, Metallurgy, Materials Science, Applied Mathematics & Modeling, or a related discipline, with excellent academic credentials. Experience or advanced knowledge in scientific programming is essential. Candidates with knowledge or experience in computational fluid dynamics, computational mechanics, crystal plasticity, phase-field modeling, Lattice Boltzmann method, or other computational materials science techniques are strongly encouraged to apply. Close interactions with industrial stakeholders are expected; therefore the ability to work as part of a team is essential.


The first contract will be for one year, but the overall project is budgeted for 3 years, such that the position is expected to be renewed yearly up to a total of 3 years.


Interested candidates should submit their Curriculum Vitae, a brief cover letter addressing their motivation and scientific interests, as well as academic credentials.


  • Full-time contract including social security coverage
  • The post will remain active and open until all positions are filled
  • Expected start date: Early 2022
  • Duration: 1 year, renewable yearly for up to 3 years


The working language of the Institute is English. Full command of the English language is required in all positions.

IMDEA Materials Institute is committed to equal opportunities, diversity and the promotion of a healthy work environment and work-life balance. Female applicants are encouraged to apply to our research and technical positions.

Applications are processed upon reception. Once the minimum publication days have passed, the position might be closed, so we encourage early application.

Besides on-the-job technical training, IMDEA Materials Institute is committed to training the Institute’s scientists and staff in “soft” or transversal skills. See the available training here.

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