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Contamination is a limiting factor in reducing fabrication length-scales in high-tech applications, but before one can start to control it, one has to understand its source.
After completion of his internship at Fokker Landing Gear, Sven Sperling acquired his Bachelor degree from the Fontys University of Applied Sciences located in Eindhoven. He continued his studies at the Eindhoven University of Technology (TU/e), where he received his MSc. degree in Mechanical Engineering. During his Master's study Sven joined the Mechanics of Materials research group, where he cultivated an interest in numerical mechanics. During his graduation project he compared the performance of enriched computational homogenization schemes applied to hyperelastic mechanical metamaterials. In 2019 Sven started his PhD at the Mechanics of Materials group, focusing on wear particle detachment from silicon wafers.
Sven Sperling is a PhD candidate in the Mechanics of Materials research group at the department of Mechanical Engineering. His PhD research focuses on unraveling the mechanics involved in wear particle detachment from silicon wafers induced by sliding contact with diamond-like carbon coated machine parts. The main goal is to establish a numerical model of a scratch test at the micrometer length scale involving pressure induced phase transitions. Exploiting these simulations with corresponding experimental validation will provide insightful data about the mechanisms involved in wear debris formation. The acquired information can be used to predict and control contamination in places required to be immaculate.
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15/04/19 → 15/04/23
Project: Research direct
- 1 Article
A continuum consistent discrete particle method for continuum-discontinuum transitions and complex fracture problemsSperling, S. O., Hoefnagels, J. P. M., van den Broek, K. & Geers, M. G. D., 15 Feb 2022, In: Computer Methods in Applied Mechanics and Engineering. 390, 24 p., 114460.
Research output: Contribution to journal › Article › Academic › peer-reviewOpen AccessFile26 Downloads (Pure)
Comparison of enriched computational homogenization schemes applied to pattern-transforming elastomeric mechanical metamaterialsAuthor: Sperling, S. O., 4 Mar 2019
Student thesis: MasterFile