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engineering, or closely related fields Excellent skills in development of complex optical systems Experience in optical simulation skills (Preferably in Zemax) Strong programming skills (preferably in Python
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fast, efficient, and versatile reconfigurable thermal landscapes controlled by light polarisation, power and illumination patterns (https://dx.doi.org/10.1039/C9NR01628G, https://doi.org/10.1103
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professor. The group has three research tracks: freeform design, imaging optics and improved direct methods; for more details see https://martijna.win.tue.nl/Optics/ . The following mathematical disciplines
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State Physics, Institute for Solid State Physics and Optics, HUN-REN Wigner Research Center for Physics, Budapest, Hungary, which is funded by the National Research Development and Innovation Office
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the optical tweezers Use and further develop simulation tools to design and benchmark control strategies before deploying them on the microscope Integrate your software with the microfluidic live-cell imaging
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). • Design the testbed architecture, including a 532 nm laser source and a Martian backscatter simulator. 2. Laboratory implementation • Assemble and align the full optical bench. • Develop or integrate a low
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ranges, fibre-optic sensors, lidars, optical communication systems and quantum technologies. In these areas, the section is developing laboratory test setups and simulation tools. Depending on your
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in silicon and 2) interface them with optical circuits to process the emitted photons. The tasks will involve designing and testing components in silicon photonics to interface with quantum emitters
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optical spectroscopy, including measurements as a function of temperature, oxygen concentration, and pH. Calibration of the materials as sensors to measure temperature, oxygen, and pH values in cells
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radiation in the 20–40 eV range, corresponding to the expected operating values for the abovEF instrument under development. Analysis of the detector's response serves to optimize the spectrometer's optical