Sort by
Refine Your Search
-
Listed
-
Category
-
Country
-
Employer
- The University of Manchester
- CNRS
- Nature Careers
- Cranfield University
- Monash University
- NTNU - Norwegian University of Science and Technology
- Newcastle University
- European Synchrotron Radiation Facility
- Forschungszentrum Jülich
- LEM3
- NTNU Norwegian University of Science and Technology
- University of Birmingham
- University of Warwick
- cnrs
- Delft University of Technology (TU Delft)
- ETH Zürich
- Ecole Centrale de Lyon
- ICN2
- IRTA
- Imperial College London
- Institut polytechnique UniLaSalle
- LSPM , CNRS 3407
- Leibniz
- Loughborough University;
- Luleå tekniska universitet
- Max Planck Institute for Sustainable Materials GmbH, Düsseldorf
- Max Planck Institute of Microstructure Physics •
- Pennsylvania State University
- Queensland University of Technology
- Slovak University of Agriculture in Nitra
- Stockholms universitet
- Swansea University
- Technical University of Denmark
- UNIVERSIDAD DE BURGOS
- University of Amsterdam (UvA)
- University of Cambridge
- University of Greenwich
- University of Newcastle
- University of Oxford
- University of Twente (UT)
- Université Gustave Eiffel
- 31 more »
- « less
-
Field
-
microstructure, residual stress, and distortion of the deposited parts, all of which significantly impact their mechanical properties and overall performance. Consequently, accurately determining and effectively
-
performance compared with existing alloys. The properties of this alloy depend on careful control of the microstructure, in particular the second phase particles and recrystallization. The project aims
-
comprise the metallurgical synthesis of metallic glasses and their microstructural characterization, the implementation of strategies for electrochemical surface modifications and advanced chemical coating
-
out within the DFG Priority Programme “DaMic - Data-driven Alloy and Microstructure Design of Sustainable Structural Metals” (SPP 2489), in close collaboration with a research partner responsible for
-
the final weld. Microstructural simulation of grain sizes and morphology after solidification will be developed together with simulation of metallurgical phase transformations at microscale. Combining
-
environments essential Interest in THC-modelling desirable, previous experience is an advantage Experience in mineralogical and microstructural rock characterisation is a plus Ability to work independently in a
-
. The temperature field generated by the interaction between the arc and the material plays a critical role in determining the microstructure, residual stress, and distortion of the built parts—all of which
-
the material in the facility available at Cranfield’s high temperature corrosion laboratory. A detailed analytical phase. for better understanding of the microstructure, requires working on the advanced
-
in Python. Interest in (or prior exposure to) metamaterials / architected materials (e.g., lattices, TPMS, graded microstructures) and homogenisation concepts. Basic understanding of anisotropy and
-
. Elements such as copper and tin, which are the focus of this project, enrich at grain boundaries during thermo-mechanical processes used to achieve the desired steel microstructure. In this project, you will