Sort by
Refine Your Search
-
Listed
-
Category
-
Country
-
Employer
- Newcastle University
- Technical University of Denmark
- CNRS
- University of Birmingham
- Delft University of Technology (TU Delft)
- The University of Manchester
- DAAD
- ETH Zürich
- Empa
- Linköping University
- Nature Careers
- University of Exeter
- University of Nottingham
- University of Sheffield
- Universität Bern
- Utrecht University
- Academic Europe
- Arts et Métiers Institute of Technology (ENSAM)
- Brunel University London
- Delft University of Technology (TU Delft); Published yesterday
- Dublin City University
- Ecole Polytechnique Federale de Lausanne
- Eindhoven University of Technology (TU/e); yesterday published
- Imperial College London;
- Inria, the French national research institute for the digital sciences
- KU LEUVEN
- King's College London Department of Engineering
- Leiden University
- Leiden University; today published
- Manchester Metropolitan University;
- Mälardalen University
- Queensland University of Technology
- TU Darmstadt
- Technical University of Munich
- The University of Manchester;
- UCL
- Universitat Autonoma de Barcelona
- University of Adelaide
- University of Bristol;
- University of Cambridge;
- University of Hull
- University of Newcastle
- University of Plymouth
- University of Sheffield;
- Utrecht University; Published yesterday
- 35 more »
- « less
-
Field
-
in conjunction with the industry partner, this PhD project aims to develop a reliable numerical modelling framework capable of: (i) simulating coupled heat and fluid flow within deep geothermal
-
naturally-occurring brines derived from granite-water interaction and thereby avoiding energy intensive, extractive mining. Faults play a key role in these systems by acting as fluid flow conduits and sites
-
for all. This PhD project aims to develop a robust numerical modelling framework to improve understanding and prediction of heat and fluid flow in deep geothermal reservoirs. Using geological, hydrological
-
-dependent Waves) 3) Keeler, J. S. et al. ``Exact solutions for submerged von Kármán point vortex streets co travelling with a wave on a linear shear current'', J. Fluid Mech. 969, A5, 2023. (Waves with
-
flow-acoustics interactions. In this study, we will extend our high-fidelity aeroacoustics simulation framework [3] to further model the elastic airfoil trailing edge and study the interactions
-
Are you passionate about understanding the underlying physical principle of noise generation by unsteady turbulent flows? Do you want to contribute to cutting-edge research that will lead to a
-
Requirements Specific Requirements The candidate should have basic knowledge: (a) in fluid dynamics and thermodynamics (knowledge in multiphase flows will be a plus), (b) numerical modelling with Finite Volume
-
differential equations and boundary conditions describing heat and fluid flow will be embedded directly into the learning process to constrain model training and reduce data requirements. Time- and space
-
applied physics other related disciplines. Demonstrated knowledge in at least one of the following areas: porous media flow computational fluid dynamics (CFD) pore-network modelling lattice Boltzmann method
-
used synthetic refrigerants. Methodological approach: 1. State of the art on working fluids and the regulatory framework. An in-depth literature review will be conducted to identify current and emerging