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Field
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We are looking for a highly motivated candidate to pursue a PhD programme titled "CFD-informed finite element analysis for thermal control in wire-arc directed energy deposition." This research
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framework exploiting the use of physical and geometrical conservation laws in a variety of spatial discretisation schemes (i.e. Finite Element, Finite Volume, Meshless). The resulting conservation-type
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are contaminated with (for example) Cu or Zn either prior to welding (or to weld repair), the potential exists for cracking through either liquid metal embrittlement (LME) or solid metal-induced embrittlement (SMIE
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the effect of minor elements addition and their interplay with elements from EoL-scrap on the alloy corrosion performance. To investigate the mechanisms of the effects of different elements
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the rate of oxidation and corrosion, and the addition of other elements to stabilise the microstructure and increase the service life of the metal and thus reduce the need for component replacement
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efficiency. Secondly, they are also resistant to corrosion resulting in lower maintenance costs and longer component lifetimes. Furthermore, they require significantly less energy to produce and are easier
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Fe7W6 intermetallic at the interface. New manufacturing strategies are needed to create dissimilar material bonds to tungsten for component joining and the validation of their structural integrity
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EPSRC Centre for Doctoral Training (CDT) PhD in Digital Metal with BAE Systems (Enhanced Stipend) Solid-state Additive Manufacturing of Nickel Aluminium Bronze alloys Background UK Applicants
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EPSRC Centre for Doctoral Training (CDT) PhD in Digital Metal with BAE Systems (Enhanced Stipend) Solid-state Additive Manufacturing of Nickel Aluminium Bronze alloys Background UK Applicants
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either liquid metal embrittlement (LME) or solid metal-induced embrittlement (SMIE). The aim of this project is to establish the potential for either LME (during welding) or SMIE (during service) in common