Sort by
Refine Your Search
-
Listed
-
Category
-
Country
-
Employer
- DAAD
- Curtin University
- University of Basel
- University of Texas at El Paso
- Utrecht University
- Biology Centre CAS
- KU LEUVEN
- Lulea University of Technology
- The University of Manchester;
- Umeå University
- University of Exeter;
- Cranfield University
- Delft University of Technology (TU Delft)
- ETH Zürich
- Ecole Centrale de Nantes
- Forschungszentrum Jülich
- Luleå University of Technology
- Luleå University of Tehnology
- Max Planck Institute for Sustainable Materials •
- Medical University of Lublin
- Murdoch University
- NTNU Norwegian University of Science and Technology
- Nature Careers
- Newcastle University
- Stockholm University
- Tallinn University of Technology
- Technical University Of Denmark
- Technical University of Denmark
- Technical University of Munich
- UCL
- Universidade de Coimbra
- University of Bayreuth
- University of Birmingham
- University of Göttingen •
- University of Southern Denmark
- Uppsala universitet
- jobs.ac.uk
- 27 more »
- « less
-
Field
-
build the sustainable companies and societies of the future. Our research in mineral processing consists of three pillars: material characterization (mineralogical and particle analyses), unit operations
-
that you will help us to build the sustainable companies and societies of the future. Our research in mineral processing consists of three pillars: material characterization (mineralogical and particle
-
, our research in mineral processing consists of three pillars: material characterization (mineralogical and particle analyses), unit operations (such as comminution and separation processes) as
-
build the sustainable companies and societies of the future. In line with the green transition and the striving for a sustainable supply of critical raw materials, our research in mineral processing
-
project will develop the first sustainable, closed-loop recycling process for polymer-bonded NdFeB magnets. The research will harness chemical recycling approaches to selectively dissolve the polymer matrix
-
-funded project HYDROSPHEAR. The project will explore how H2O may be stored in hydrous minerals of the Earth's lower mantle by constraining their stability limits and physical properties by means
-
underlying these processes remain poorly represented. This PhD project aims to fill that gap by using molecular simulations to quantify the interactions of SOM and EPS with water and minerals, and to connect
-
, physical and chemical processes are likely to have led to significant changes in the physical, structural and chemical properties of the zeolite minerals over this period. For example, the high doses of both
-
through the caprock but cations just diffuse through it. Geo-chemical alteration of minerals prone to acid attack, can occur because of the chemical disequilibrium between the brine, saturating the clayey
-
across conditions and integrate phenotypic readouts with functional omics to identify the processes underlying key performance changes. You will work closely with a postdoc evolving these consortia and