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of the chemicals in biological tissues without the use of labels. MSI can help us better understand and diagnose diseases such as, for example, cancer. Most MSI is performed using ultraviolet (UV) lasers and an
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laser pulses to create (periodic) assemblies of nanosized chiral spin textures on demand. These tunable structures are predicted to host topological spin waves, and will provide a unique playground to
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instruments, such as detectors and lasers operating in the UV to FIR wavelength ranges, fibre-optic sensors, lidars, optical communication systems and quantum technologies. The Section is staffed with around 25
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and imaging capabilities, and on applying THz (emission) microscopy to study 2D materials and 2D heterostructures. The microscope will use femtosecond lasers to generate and detect terahertz pulses
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of the Next Generation Gravity Mission (NGGM) will rely on the high-accuracy measurement of the variation in inter-satellite distance due to the time-varying gravity field via a laser tracking instrument and
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at NIOZ (e.g. confocal laser scanning microscopy laser ablation-ICP-MS,) you will investigate ion uptake mechanism and crystallization dynamics: this will help predicting future marine calcification rates
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to achieve continuous Bose-Einstein condensation [Nature 606, 683 (2022) ]. We are building two types of such clocks: a superradiant clock and a zero-deadtime clock. A superradiant clock is a laser that lases
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radar interferometry (InSAR) integrated with GNSS and airborne laser scanning. The PhD candidate will: Develop a recursive, dynamic monitoring strategy for near-continuous 3D surface displacement