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Field
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mechanical properties, based on vibrations generated by ambient noise in the reactor. Noise sources in the reactor can be of various origins. Given the lack of knowledge or the difficulty in determining
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probabilistic modeling of weak signals in the image related to sensor noise developed on JPEG images [Taburet et al., 2020, Giboulot et al.,2021, Giboulot et al.,2022]. The modeling of the sensor noise will be
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, allowing efficient transduction of mechanical vibrations into electrical signals at millikelvin temperatures. These devices support coupling between electronic, spin, and mechanical states. The proposed
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photometry and interferometric scattering microscopy, we will explore novel illumination and detection strategies to enhance signal-to-noise ratios and improve the accuracy and precision for molecular
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. Empa is a research institution of the ETH Domain. Environmental noise from air and ground-borne traffic is an underestimated problem. In our research group, we develop new technical solutions to mitigate
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(e.g., XES, XANES/EXAFS, resonant/non-resonant scattering). Diagnose and mitigate performance limiters (e.g., vibration, magnetic fields, microphonics, thermal loading, stray light), and contribute
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of Science at UvA. What are you going to do? The aim of the project is to use advanced Machine Learning techniques to predict the anharmonic vibrational spectra of large Polycyclic Aromatic Hydrocarbon (PAH
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vibrating aluminum drumheads [Nature 556, 478 (2018) , Science 372, 625 (2021) ]. Project 1: Gravitational coupling between nonclassical masses This project aims to address one of the great unresolved
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at deep cryogenic temperatures in dilution refrigerators. Notably, we have demonstrated quantum entanglement between two micromechanical oscillators realized as vibrating aluminum drumheads [Nature 556, 478
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transport properties will be investigated using I-V and C-V measurements. Advanced electrical measurements, such as deep level transient spectroscopy (DLTS) or low-frequency noise spectroscopy, will also be