Sort by
Refine Your Search
-
Listed
-
Category
-
Employer
- University of Sheffield
- Cranfield University
- University of Nottingham
- AALTO UNIVERSITY
- Brunel University London
- King's College London Department of Engineering
- Manchester Metropolitan University
- Manchester Metropolitan University;
- The University of Edinburgh
- The University of Manchester
- University of Birmingham
- University of Birmingham;
- University of East Anglia
- University of East Anglia;
- University of Exeter
- University of Hull
- University of Newcastle
- University of Surrey
- 8 more »
- « less
-
Field
-
allowed computational fluid dynamics (CFD) to flourish, becoming an indispensable for many industries. Simulating the full Navier-Stokes equations is computationally prohibitive for most applications, so
-
confined battery geometries. Advanced modelling—including computational fluid dynamics (CFD) and transient thermal analysis—is required to accurately capture heat flux distributions, temperature uniformity
-
group, you will become part of a vibrant research environment specialising in nonlinear and quantum fluid dynamics. You will also have the opportunity to visit partner institutions and work with leading
-
for fusion components. This framework foresees two building blocks: high-fidelity Computational Fluid Dynamics (CFD) simulations of boiling flows within complex geometry using opensource software and cutting
-
are invited for a fully-funded Industrial Doctoral Landscape Award, offered in partnership with Rolls-Royce, to tackle key challenges in the design of aeroengine oil systems using multiphase Computational Fluid
-
(SLA) printing and wind tunnel testing at Aston Martin Aramco Formula One and Manchester Met’s PrintCity. Collaborate with experts in additive manufacturing, fluid dynamics, and data science, producing
-
mechanics, and analytical and numerical methods to solve partial differential equations. Excellent oral and written communication skills. Prior experience in computational fluid dynamics or active matter will
-
to validate computational fluid dynamics modelling to determine drag and vortex-induced vibrations on dSPCs associated with biofouling. Better understanding of the hydrodynamic consequences on dSPCs from key
-
the interaction between the structure of CFM and dynamic performance of the flow. The aim will be achieved through the following objectives: Develop a novel approach to investigate the fluid-solid coupling effect
-
, multidisciplinary research environment combining experimental surface physics, nanotechnology, and fluid dynamics. In return, we are looking for a candidate who has: A suitable academic background in physics