About the project
This project aims to develop advanced nonlinear damping mechanisms for space exploration and extraterrestrial colonisation. Combining numerical modelling, experiments, and compliant mechanisms, this research tackles regolith interactions and extreme conditions to improve structural resilience.
Future space missions require lightweight, energy-efficient structures that can withstand harsh environments, including extreme temperature shifts, dynamic loads, and abrasive regolith interactions. Traditional damping solutions often rely on friction-based mechanisms, which are prone to wear and mechanical failure in space.
This project, in collaboration with the European Space Agency (ESA), aims to develop innovative nonlinear damping solutions by integrating compliant mechanisms and advanced structural dynamics to improve longevity and resilience in space structures.
You will:
- develop advanced analytical and numerical models to predict and optimise damping behaviour
- simulate regolith interactions and their impact on structural degradation
- conduct experimental validation using high-speed imaging, laser vibrometry, and thermo-imaging at the University of Southampton’s cutting-edge facilities
- collaborate with ESA engineers to ensure real-world applicability and contribute to next-generation space technologies
This research will have a direct impact on future lunar habitats, planetary surface operations, and spacecraft structural components, providing a robust, long-term damping solution for extreme environments.
You will gain expertise in structural dynamics, nonlinear mechanics, and aerospace engineering, positioning yourself for careers in space agencies, research institutions, and aerospace industries.
This is a unique opportunity to work at the forefront of space engineering research, contributing to the advancement of structural resilience for future space missions.
