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QMLA group in the Department of Physics and Astronomy The Quantum Metrology and Laser Applications group at LaserLaB, Vrije Universiteit Amsterdam, is a very international group, consisting of some
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topics or with experience in quantum technology, spectroscopy, and/or laser physics, who wishes to work with us in the international and stimulating environment of the joint Quantum Metrology group
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produced from tiny tin droplets that are heated by powerful laser pulses. At ARCNL, we are now thinking about the next generation of light sources: Can we make more efficient and more powerful EUV sources
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, enhancing silicon platforms with efficient III-V active functions (lasers, amplifiers, modulators, detectors) requires the design and fabrication of tailored InP coupons, which can be transferred using
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, absorption spectroscopy with broadband, laser-based infrared sources is emerging as a promising and effective tool. In particular, the newly developed high-power intrapulse difference frequency generation
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photonic integrated circuits. (PICs). Specifically, we will be looking at optical amplifiers, lasers and photodetectors, with a focus on noise and high-power behavior. Such compact models will propel
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polymer rheology and can implement constitutive models in Matlab or Python. Laser-assisted automated fiber placement Laser-assisted fiber placement (LAFP) is an additive manufacturing technology for
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integrated supercontinuum laser based FTIR measurements in variation of the total arc length, establishing radial gas and plasma temperature profiles with laser scattering at/around the arc exit in variation
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objectives include establishing evolution of species distributions by in situ line-of-site integrated supercontinuum laser based FTIR measurements in variation of the total arc length, establishing radial gas
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other wavelength ranges. To fully exploit this potential, new photonic building blocks must be developed, including lasers, modulators, photodetectors, and passive components. Extending their operation to