3 PhD positions funded through the Horizon Europe Marie Skłodowska-Curie Actions (MSCA) Doctoral Networks as part of the “Bridging Models at Different Scales To Design New Generation Fuel Cells for Electrified Mobility (BLESSED)” project.
Description:
We are seeking a highly motivated and talented postdoctoral researcher to join our dynamic research team at the University of Louisville, focused on investigating the high-velocity impact of architected materials.
Responsibilities:
Dear colleagues,
Our TRIPOP team is offering a one-year post-doctorate in collaboration with Safran Tech on
Comparison of numerical modelling methods for the dynamics of flexible multi-body systems in the presence of contact and friction.
https://jobs.inria.fr/public/classic/fr/offres/2023-06439
This offer may be of interest to one of your students, or someone in your network.
Best regards
We will have an opening for a postdoctoral position at the CC&B, University of Milan in the group of Prof. Zapperi. We are looking for candidates with strong programming skills who are interested in working at the frontier between academic and industrial research. The candidates should have a Ph. D in computer science, computational materials science, physics, mathematics or engineering.
I am a postdoc in the department of mechanical and aerospace engineering at UCLA. I got a bachelor's degree in Theoretical and Applied Mechanics from Harbin Institute of Technology (ranking 1st in our major). I obtained my PhD in Mechanical Engineering from the University of Maryland, College Park.
Additive manufacturing of metal alloys yields great potential for the aerospace industry (and others) as it allows the generation of geometrically complex structures with high specific strength, low density and high corrosion resistance. For example, General Electric has demonstrated the possibility of printing titanium fuel injectors for their LEAP engine, Boeing incorporated more than 300 printed parts in their 777X airplane … For such critical applications, the structural quality of printed parts is of utmost importance. Small deviations in print conditions, e.g.
Over the past years, UGent-MMS has developed a stand-alone topology optimization code for additive manufacturing applications. The topology optimization software can deal with thermo-mechanical coupled problems, combined with multi-material selection. Such features are not available in any commercial topology optimization code.
The code can also deal with large industrial optimization problems, with millions degrees of freedom in three-dimensional finite element models.
We are looking for a postdoctoral researcher for a research project on textile modelling. In this project, the main purpose is to develop a multi-scale textile modelling framework that allows accurate simulation of textile manufacturing processes such as yarn unwinding from a bobbin, weft insertion during weaving, stitching and tufting. This framework is implemented using finite element modelling as well as virtual fibre modelling. Key here are the dynamics of these systems as most textile production happens at high speeds.
We are looking for a PhD student for a research project on textile modelling and characterization. In this project, the main purpose is to develop a multi-scale textile modelling framework that allows accurate simulation of textile manufacturing processes such as yarn unwinding from a bobbin, weft insertion during weaving, stitching and tufting. Besides a strong numerical research focus, there is also an experimental research track focusing on advanced mechanical testing of textile materials and their connections, both on lab-scale and industrial scale (e.g.
We are looking for a PhD student for a research project on textile modelling. In this project, the main purpose is to develop a multi-scale textile modelling framework that allows accurate simulation of textile manufacturing processes such as yarn unwinding from a bobbin, weft insertion during weaving, stitching and tufting. This framework is implemented using finite element modelling as well as virtual fibre modelling. Key here are the dynamics of these systems as most textile production happens at high speeds.
