NÚMERO 212
Miércoles 30 de octubre de 2024

56921

JUNIOR RESEARCHER
Position: Junior researcher in computational fluid dynamics (CFD).
Offer date: DOE publication.
Project: CIIAE – REF. IJ-CFD (HIDRÓGENO Y POWER-TO-X).
Department: Hydrogen and Power-to-X.
Estimated starting date: 4th Quarter 2024.
Workplace:

University of Extremadura. Cáceres campus
Topic: Rigorous multi-scale CFD modelling platforms will play a key role in
developing and scaling up innovative energy storage, power-to-X and hydrogen conversion systems in the future. Computational modeling of the interplay
between transport phenomena, material properties, and electrochemistry
provides invaluable insight into the design, potential, and limitations of new
technologies. CFD modelling allow us to explore the design space, create digital twins and find the most promising systems and process units to be studied
experimentally; it allows us to optimize their operation and address the question of how to scale small units for full-scale application. The successful candidate is expected to carry out the following tasks:
—D
 evelop, create, and analyse CFD simulations of various types of energy storage, Power-to-X and hydrogen technologies.
—F
 oster collaborations with experimental researchers from CIIAE and
beyond.
—P
 rovide recommendations to decision makers based on modelling results.
—A
 chieve successful collaboration with universities, research institutes
and companies at national and international level.

Tasks to be developed:

—W
 rite publications as first author and co-author (e.g., 1.5 paper per
year in top-ranked journals).
—W
 rite research proposals and contribute to securing competitive funding, both private and/or public.
—U
 ndertake project management and project administration responsibilities (internal and external) within the department, and within the
CIIAE.
—B
 ecome gradually more independent, in order to conduct, manage and
lead an independent project.
Challenge: The multi-scale nature of the processes driving the energy transition presents a significant scientific challenge in CFD. The underlying physics
span a broad range of scales, from microscale properties that influence reactivity and advanced material development, to mesoscopic phenomena—such as
bubbling and clustering—that govern transport and flow optimization, to the
macroscopic limitations affecting mass and heat transport in full-scale units,
such as reactors and fuel cells. A CFD methodology that is rigorous, validated,
and tailored is essential for reliably predicting the performance and durability of next-generation energy storage, Power-to-X, and hydrogen conversion
systems.