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the development of compact device modeling, SPICE simulation and with programming skills in general programs such as python, Matlab or similar. Experience on memristors is also acknowledged. Experience in circuit
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Application deadline: 30/04/2026 Research theme: Nuclear Engineering How to apply: https://uom.link/pgr-apply-2425 This 3.5-year PhD project is fully funded; home students are eligible to apply
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. Contribute to Europe’s photonics ecosystem through involvement with PITC, JePPIX, and Chips for Europe initiatives Where to apply Website https://www.academictransfer.com/en/jobs/358372/phd-on-compact-models
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high cycle efficiency, compact equipment size and their applicability to the exploitation of industrial waste heat sources. In project REVCO2, four research laboratories (CETHIL, Lafset, LMFA and LUSAC
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an earned doctorate (PhD) and eligibility for RN licensure in Pennsylvania or a compact state. Salary and academic rank are commensurate with qualifications and experience. Apply Now: Applications will be
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efficiency, compact equipment, and adaptability to a wide range of heat sources, including next-generation nuclear reactors and industrial waste heat. This PhD thesis is part of the PEPR REVCO2 project, a
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for diverse molecules; and c) potential energy surfaces for the few lowest electronic states of compact-size molecules and compounds representative of typical photochemical reactions. In each case, the PhD
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of the breast duct and the mechanical conditions (including cell compaction and acting forces) influencing cancer cell migration and invasion. The proposed system will enable dynamic control of the invasion
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, kinetic and mass-transfer studies, and reactor modeling with experimental validation. The goal is to realize a compact, efficient reactor system. Your work contributes directly to the transition from fossil
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and photonic synchronization. You will develop and integrate optical amplifiers on chip to boost the performance of microresonator frequency combs. The goal: compact, energy-efficient photonic systems