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form of energy–e.g. electrical, magnetic, acoustic, or chemical–into mechanical motion. These swimmers are expanding the frontiers of micro-engineering and can be used in tasks such as chemical analysis
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group with structured training and strong technical support. 2. Candidate profile This project is ideal for candidates from Mechanical, Electrical, Biomedical, Materials Engineering, or related
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from Mechanical, Biomedical, Materials Engineering, or related disciplines. A strong motivation for interdisciplinary biomedical engineering research is essential. Applicants should hold (or expect
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positioned to benefit any applicant interested in a future career in healthcare technology. The University emphasises the clinical translation of innovative research to ensure real-world impact through
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avenues by enabling chronic, gut-based monitoring of neuroendocrine activity for applications such as closed loop therapeutics. The proposed PhD project sits at the interface of biomedical engineering
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shift from microwaves to mm-waves (ca. 30 – 300 GHz) or even Terahertz frequencies (ca. 0.3 – 1 THz). Current on-chip interconnect technology relies on printed circuit board (PCB), which is not suitable
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. This PhD project will explore a novel approach: leveraging polymeric microelectromechanical systems (MEMS) technology to create a miniaturised micropump-based ingestible capsule that can actively deliver
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surface roughness, and undergoes absorption and scattering by molecules and suspended particulates in the atmosphere. Any viable mobile radio communications technology at THz frequencies must operate both
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Main description: Native mass spectrometry is an expanding structural biology tool to elucidate the function of protein complexes. Excitingly, the demand for this technology is increasing. However
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Requirements: Applications are welcome from highly motivated candidates with a background in: Civil Engineering, Materials Science, or related disciplines. Experience or interest in Applied Rheology, Concrete