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conversion. Our research is at the interface between fundamental quantum physics, thermodynamics, nanotechnology, and nanofabrication. Project background This project aims to harness the remarkable properties
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residual and end-of life products. The division has access to well-equipped laboratories for hydrometallurgical and pyrometallurgical studies, materials characterization and thermodynamics. Subject
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. Although the development of thermodynamically stable inhibitors is possible, this typically comes at a price of increased toxicity and reduced bio-degradability. Due to the ever-tightening legislation
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not sufficiently understood. This involves complex physics at the interface of plasma physics, shock physics, material science and thermodynamics. The objective of this project is the computational
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; EPSRC Centre for Doctoral Training in Green Industrial Futures | Bath, England | United Kingdom | 12 days ago
Mathematical Modelling of kinetic and thermodynamic performance of material to optimize the production process. The research has significant real world impact. It is expected to deliver a step change in
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skills in fluid dynamics, thermodynamics, or computational modeling are a plus. Start Date: Flexible – 2025 entry Location: University of Sheffield, Leading UK university in partnership with John Crane Ltd
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quantum thermodynamics. The overarching aim of this theoretical physics PhD research is to better understand the fundamental physical laws which govern how energy and information flow in the quantum world
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conformations in an attempt to reach thermodynamic states of lower energy.Bringing together the expertise of two labs at ULB (https://chimpoly.ulb.be and http://dynamics.ulb.be), this project will investigate
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at Cranfield. The overall aim of this PhD project is to analyse droplet impact mechanics along with the freezing thermodynamics under high airspeeds to gather important insights into ice adhesion
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made on the surface of each contaminated plate, and the weld regions will be inspected for signs of LME/SMIE using dye-penetrant testing and microscopy. ThermoCalc (thermodynamic) simulations will be