Narrow-band few photon filter and phase lock control for EIT with Cs in a nanofiber dipole trap

Nicht angegeben.This Master thesis was performed around an experiment aiming at the investigation of the optical properties of laser cooled Cesium (Cs) atoms dipole trapped in the evanescent field of an optical nanofiber. Two parts of the total experiment are covered in this thesis. The focus of the first part is the beam preparation of the EIT control and probe lasers which ensures a phase stable joint performance of both beams necessary for the implementation of EIT. This is achieved by an optical phase-locked loop (OPLL) locking the probe to the control laser. The performance of this OPLL is examined with an out-of-loop phase noise measurement. The second part of this thesis concerns the efficient detection of the prospective few-photon EIT probe signal, which will be immersed in a broadband noise background. While the weak EIT probe signal (<pW power) is expected to be extremely narrow-band (<kHz) the noise has a power of ~5pW within a wavelength window of 10nm around the probe wavelength. Conventional optical filters fail in efficiently separating the signal from the fluorescence. Here, two strategies are elaborated theoretically aiming at a reasonable solution for narrow-band few-photon filtering: one employing a diffraction grating and another based on homodyne detection. Experimental proposals for filters based on both options are made, followed by an experimental realization and analysis of a compact test setup, a homodyne saturation spectroscopy

Universal, high-fidelity quantum gates based on superadiabatic, geometric phases on a solid-state spin-qubit at room temperature

Geometric phases and holonomies (their non-commuting generalizations) are a promising resource for the realization of high-fidelity quantum operations in noisy devices, due to their intrinsic fault-tolerance against noise and experimental imperfections. Despite their conceptual appeal and proven fault-tolerance, for a long time their practical use in quantum computing was limited to proof of principle demonstrations. Only in 2012 Sj\"oqvist et al. formulated a strategy to generate non-Abelian (i.e. holonomic) quantum gates through non-adiabatic transformation. Successful experimental demonstrations of this concept followed on various physical qubit systems and proved the feasibility of this fast, holonomic quantum gate concept. Despite these successes, the experimental implementation of such non-Abelian quantum gates remains experimentally challenging since in general the emergence of a suitable holonomy requires encoding of the logical qubit within a three (or higher) level system being driven by two (or more) control fields. A very recent proposal by Liang et al. offers an elegant solution generating a non-Abelian, geometric quantum gate on a simple, two-level system driven by one control field. Exploiting the concept of transitionless quantum driving it allows the generation of universal geometric quantum gates through superadiabatic evolution. This concept thus generates fast and robust phase-based quantum gates on the basis of minimal experimental resources. Here, we report on the first such implementation of a set of non-commuting single-qubit superadiabatic geometric quantum gates on the electron spin of the negatively charged nitrogen vacancy center in diamond. The realized quantum gates combine high-fidelity and fast quantum gate performance. This provides a promising and powerful tool for large-scale quantum computing under realistic, noisy experimental conditions

Measuring environmental quantum noise exhibiting a non-monotonous spectral shape

Understanding the physical origin of noise affecting quantum systems is important for nearly every quantum application. Quantum noise spectroscopy has been employed in various quantum systems, such as superconducting qubits, NV centers and trapped ions. Traditional spectroscopy methods are usually efficient in measuring noise spectra with mostly monotonically decaying contributions. However, there are important scenarios in which the noise spectrum is broadband and non-monotonous, thus posing a challenge to existing noise spectroscopy schemes. Here, we compare several methods for noise spectroscopy: spectral decomposition based on the Carr-Purcell-Meiboom-Gill (CPMG) sequence, the recently presented DYnamic Sensitivity COntrol (DYSCO) sequence and a modified DYSCO sequence with a Gaussian envelope (gDYSCO). The performance of the sequences is quantified by analytic and numeric determination of the frequency resolution, bandwidth and sensitivity, revealing a supremacy of gDYSCO to reconstruct non-trivial features. Utilizing an ensemble of nitrogen-vacancy centers in diamond coupled to a high density $^{13}$C nuclear spin environment, we experimentally confirm our findings. The combination of the presented schemes offers potential to record high quality noise spectra as a prerequisite to generate quantum systems unlimited by their spin-bath environment

Il bizzarro mondo dei quanti

Scritto prima dell'esame di maturità da una giovane di eccezionale talento, questo libro colma il vuoto esistente tra la letteratura divulgativa sulla fisica quantistica, che normalmente evita ogni formula matematica, e la letteratura specialistica, ben farcita, invece, di matematica avanzata. L'autrice, appena diciannovenne, con l'ausilio della sola matematica della scuola superiore, introduce il lettore ai principi della fisica dei quanti. Se ne ricava uno sguardo profondo sul microcosmo, il regno affascinante delle particelle elementari: oggetti il cui comportamento si distingue in modo drastico e fondamentale da tutto ciò a cui è avvezzo il nostro umano buonsenso. "Un libro... che avrei desiderato avere a 17 anni". Silvia Arroyo Camejo "In modo assolutamente preciso dal punto di vista fisico, l'autrice spiega con grande passione e divertimento i fondamenti della moderna fisica quantistica ... " Prof. Reinhold A. Bertlmann "Un libro stupefacente di un'autrice straordinaria! Si avverte il suo entusiasmo per gli enigmi e le stranezze del microcosmo in ogni paragrafo". Prof. H. Dieter Ze

Self-supervised MRI denoising: leveraging Stein’s unbiased risk estimator and spatially resolved noise maps

Abstract Thermal noise caused by the imaged object is an intrinsic limitation in magnetic resonance imaging (MRI), resulting in an impaired clinical value of the acquisitions. Recently, deep learning (DL)-based denoising methods achieved promising results by extracting complex feature representations from large data sets. Most approaches are trained in a supervised manner by directly mapping noisy to noise-free ground-truth data and, therefore, require extensive paired data sets, which can be expensive or infeasible to obtain for medical imaging applications. In this work, a DL-based denoising approach is investigated which operates on complex-valued reconstructed magnetic resonance (MR) images without noise-free target data. An extension of Stein’s unbiased risk estimator (SURE) and spatially resolved noise maps quantifying the noise level with pixel accuracy were employed during the training process. Competitive denoising performance was achieved compared to supervised training with mean squared error (MSE) despite optimizing the model without noise-free target images. The proposed DL-based method can be applied for MR image enhancement without requiring noise-free target data for training. Integrating the noise maps as an additional input channel further enables the regulation of the desired level of denoising to adjust to the preference of the radiologist

Stimulated Emission Depletion Microscopy Resolves Individual Nitrogen Vacancy Centers in Diamond Nanocrystals

Nitrogen-vacancy (NV) color centers in nanodiamonds are highly promising for bioimaging and sensing. However, resolving individual NV centers within nanodiamond particles and the controlled addressing and readout of their spin state has remained a major challenge. Spatially stochastic super-resolution techniques cannot provide this capability in principle, whereas coordinate-controlled super-resolution imaging methods, like stimulated emission depletion (STED) microscopy, have been predicted to fail in nanodiamonds. Here we show that, contrary to these predictions, STED can resolve single NV centers in 40–250 nm sized nanodiamonds with a resolution of ≈10 nm. Even multiple adjacent NVs located in single nanodiamonds can be imaged individually down to relative distances of ≈15 nm. Far-field optical super-resolution of NVs inside nanodiamonds is highly relevant for bioimaging applications of these fluorescent nanolabels. The targeted addressing and readout of individual NV^– spins inside nanodiamonds by STED should also be of high significance for quantum sensing and information applications