[ML-news] [Job][PhD positions] PhD Student in Physics-Informed Graph Neural Networks for Wind Turbine Health Monitoring at IMOS Lab - EPFL

[Olga Fink]

We are looking for a highly motivated PhD student in Physics-Informed Graph Neural Networks for Wind Turbine Health Monitoring at the IMOS Lab - EPFL as part of an ERC Consolidator Grant.

Project description

The objective of this project is to develop novel methodologies based on physics-informed graph neural networks (PI-GNNs) to understand and model the impact of operational loads on system degradation at the component level in complex engineering systems, with a particular focus on wind turbines.

 

The research will focus on explicitly integrating physical laws, load dynamics, and degradation mechanisms into graph-based models, enabling a principled understanding of how operating conditions drive the evolution of system health over time. Particular emphasis will be placed on spatiotemporal modeling of interacting subsystems, where degradation emerges from coupled physical processes across components.

The project will explore how graph-based representations can capture:
•    the propagation of loads and stresses across interconnected components,
•    the accumulation of fatigue and damage under variable loading conditions, and
•    the interaction between structural dynamics and degradation processes.

A central aspect of the research is the incorporation of physics-based inductive biases into learning architectures. This will enable the development of models that are physically consistent, interpretable, and robust under varying operating conditions, going beyond purely data-driven approaches.

Applications will include complex industrial and energy systems, with a particular focus on wind turbines, where load conditions directly influence the degradation of critical components such as blades, gearboxes, and bearings. The developed methods will contribute to improving lifetime modeling, reliability assessment, and physics-informed predictive maintenance.

This PhD position is part of an ERC Consolidator Grant, supporting cutting-edge research on health-aware control and intelligent maintenance of complex systems.

Profile

We are looking for a PhD candidate with a strong analytical background and an outstanding MSc degree in Mechanical Engineering, Computational Mechanics, Engineering Science, Physics, Applied Mathematics, or a closely related field.

 

You should have a solid foundation in machine learning (e.g., deep learning) and mathematical modeling, including experience with dynamical systems or differential equations. A strong interest in modeling physical systems and degradation processes (e.g., fatigue, damage accumulation) is expected.

 

Experience with graph neural networks or spatiotemporal models is highly desirable, as well as familiarity with physics-informed approaches that incorporate physical inductive bias into learning models.

 

Knowledge of one or more of the following areas is considered a strong asset:

• Physics-informed machine learning and hybrid modeling approaches
• Computational mechanics, structural dynamics, or fatigue and damage modeling
• Signal processing and analysis of measurement data from physical systems
• Scientific machine learning or numerical methods for physical systems

Strong programming skills and the ability to work at the interface of machine learning and physics-based modeling of engineering systems are expected.

We expect the candidate to be self-driven, with strong problem-solving abilities and out-of-the-box thinking. Professional command of English (both written and spoken) is mandatory. 

🔗 Apply here: application link (Please submit  a letter of motivation; a CV, brief research statement (one page) describing your project idea in the field of  of physics-informed graph neural networks for wind turbine health monitoring, making connections to your experience and related work from the literature, transcripts of all obtained degrees (in English), one publication (e.g. thesis or preferably a conference or journal publication, a link is sufficient)

 

Only applications submitted via the EPFL application platform will be accepted (no applications by email)

 

 

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Prof. Dr. Olga Fink

Laboratory of Intelligent Maintenance and Operations Systems

GC A3 424 (Bâtiment GC)
Station 18
CH-1015 Lausanne