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This PhD project will focus on developing, evaluating, and demonstrating a framework of novel hybrid prognostics solution for selected system use case (e.g. clogging filter, linear actuator, lithium
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and ecosystems) and fine particles (again, harmful to health, and impacting climate through scattering of radiation and influencing cloud formation). There are two key uncertainties in BVOC emissions
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into volatile chlorides. The process efficiency, however, depends on a complex interplay of particle-scale interactions and particle/solid body interactions. Current industrial practice relies heavily
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-Zhang (KPZ) universality class is a collection of models that includes the random growth of a surface over time or the behaviour of a large number of particles that move around in space and interact with
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chlorination to convert metallic impurities into volatile chlorides. The process efficiency, however, depends on a complex interplay of particle-scale interactions and particle/solid body interactions. Current
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. These changes cascade through ecosystems: plastics can alter carbon export by binding with algal cells into fast-sinking aggregates or, conversely, reducing sinking when attached to buoyant particles. Moreover
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specifically targeting stimuli-responsive materials with new structures and particle characteristics. This will be underpinned by investigating the MOF self-assembly processes and structure-property
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of nano-scale plastic particles (nanoplastics; 1-1000 nm) which represent the majority of plastic in the ocean. The impact of nanoplastics on marine life and ecosystem function requires attention
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computations possible [1]. However, proven scientific applications for quantum computing remain mostly limited to quantum chemistry, materials, and particle physics. Since CFD is one of the most demanding use
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lab is challenging the traditional view of soil-structure interaction (SSI). This project will investigate the critical role of changing particle shape on material wear and elevated stress transfer