Your search keyword '"Mielec, N."' showing total 5 results

1. Atom Interferometry with Top-Hat Laser Beams

Author

Mielec, N., Altorio, M., Sapam, R., Horville, D., Holleville, D., Sidorenkov, L. A., Landragin, A., and Geiger, R.

Subjects

Physics - Atomic Physics, Physics - Instrumentation and Detectors, Physics - Optics, Quantum Physics

Abstract

The uniformity of the intensity and phase of laser beams is crucial to high-performance atom interferometers. Inhomogeneities in the laser intensity profile cause contrast reductions and systematic effects in interferometers operated with atom sources at micro-Kelvin temperatures, and detrimental diffraction phase shifts in interferometers using large momentum transfer beam splitters. We report on the implementation of a so-called top-hat laser beam in a long-interrogation-time cold-atom interferometer to overcome the issue of the inhomogeneous laser intensity encountered when using Gaussian laser beams. We characterize the intensity and relative phase profiles of the top-hat beam and demonstrate its gain in atom-optics efficiency over a Gaussian beam, in agreement with numerical simulations. We discuss the application of top-hat beams to improve the performance of different architectures of atom interferometers., Comment: 4 pages plus references and Supplemental Material

Published

2018

2. Studies of general relativity with quantum sensors

Author

Lefevre, G., Condon, G., Riou, I., Chichet, L., Essayeh, M., Rabault, M., Antoni-Micollier, L., Mielec, N., Holleville, D., Amand, L., Geiger, R., Landragin, A., Prevedelli, M., Barrett, B., Battelier, B., Bertoldi, A., Canuel, B., and Bouyer, P.

Subjects

Physics - Atomic Physics, General Relativity and Quantum Cosmology, Quantum Physics

Abstract

We present two projects aiming to probe key aspects of the theory of General Relativity with high-precision quantum sensors. These projects use cold-atom interferometry with the aim of measuring gravitational waves and testing the equivalence principle. To detect gravitational waves, a large multi-sensor demonstrator is currently under construction that will exploit correlations between three atom interferometers spread along a 200 m optical cavity. Similarly, a test of the weak equivalence principle is currently underway using a compact and mobile dual-species interferometer, which will serve as a prototype for future high-precision tests onboard an orbiting satellite. We present recent results and improvements related to both projects., Comment: 11 pages, 7 figures, to appear in "Proceedings of the 52nd Rencontres de Moriond on Gravitation"

Published

2017

3. Exploring gravity with the MIGA large scale atom interferometer

Author

Canuel, B., Bertoldi, A., Amand, L., di Pozzo, E. Borgo, Fang, B., Geiger, R., Gillot, J., Henry, S., Hinderer, J., Holleville, D., Lefèvre, G., Merzougui, M., Mielec, N., Monfret, T., Pelisson, S., Prevedelli, M., Reynaud, S., Riou, I., Rogister, Y., Rosat, S., Cormier, E., Landragin, A., Chaibi, W., Gaffet, S., and Bouyer, P.

Subjects

Physics - Atomic Physics

Abstract

We present an underground long baseline atom interferometer to study gravity at large scale. The hybrid atom-laser antenna will use several atom interferometers simultaneously interrogated by the resonant mode of an optical cavity. The instrument will be a demonstrator for gravitational wave detection in a frequency band (100 mHz - 1 Hz) not explored by classical ground and space-based observatories, and interesting for potential astrophysical sources. In the initial instrument configuration, standard atom interferometry techniques will be adopted, which will bring to a peak strain sensitivity of 2$\cdot 10^{-13}/\sqrt{\mathrm{Hz}}$ at 2 Hz. The experiment will be realized at the underground facility of the Laboratoire Souterrain \`a Bas Bruit (LSBB) in Rustrel--France, an exceptional site located away from major anthropogenic disturbances and showing very low background noise. In the following, we present the measurement principle of an in-cavity atom interferometer, derive signal extraction for Gravitational Wave measurement from the antenna and determine the expected strain sensitivity. We then detail the functioning of the different systems of the antenna and describe the properties of the installation site.

Published

2017

4. A marginally stable optical resonator for enhanced atom interferometry

Author

Riou, I., Mielec, N., Lefèvre, G., Prevedelli, M., Landragin, A., Bouyer, P., Bertoldi, A., Geiger, R., and Canuel, B.

Subjects

Physics - Atomic Physics

Abstract

We propose a marginally stable optical resonator suitable for atom interferometry. The resonator geometry is based on two flat mirrors at the focal planes of a lens that produces the large beam waist required to coherently manipulate cold atomic ensembles. Optical gains of about 100 are achievable using optics with part-per-thousand losses. The resulting power build-up will allow for enhanced coherent manipulation of the atomic wavepackets such as large separation beamsplitters. We study the effect of longitudinal misalignments and assess the robustness of the resonator in terms of intensity and phase profiles of the intra-cavity field. We also study how to implement atom interferometry based on Large Momentum Transfer Bragg diffraction in such a cavity.

Published

2017

5. MIGA: Combining laser and matter wave interferometry for mass distribution monitoring and advanced geodesy

Author

Canuel, B., Pelisson, S., Amand, L., Bertoldi, A., Cormier, E., Fang, B., Gaffet, S., Geiger, R., Harms, J., Holleville, D., Landragin, A., Lefèvre, G., Lhermite, J., Mielec, N., Prevedelli, M., Riou, I., and Bouyer, P.

Subjects

Physics - Atomic Physics, General Relativity and Quantum Cosmology, Physics - Geophysics, Physics - Instrumentation and Detectors

Abstract

The Matter-Wave laser Interferometer Gravitation Antenna, MIGA, will be a hybrid instrument composed of a network of atom interferometers horizontally aligned and interrogated by the resonant field of an optical cavity. This detector will provide measurements of sub Hertz variations of the gravitational strain tensor. MIGA will bring new methods for geophysics for the characterization of spatial and temporal variations of the local gravity field and will also be a demonstrator for future low frequency Gravitational Wave (GW) detections. MIGA will enable a better understanding of the coupling at low frequency between these different signals. The detector will be installed underground in Rustrel (FR), at the "Laboratoire Souterrain Bas Bruit" (LSBB), a facility with exceptionally low environmental noise and located far away from major sources of anthropogenic disturbances. We give in this paper an overview of the operating mode and status of the instrument before detailing simulations of the gravitational background noise at the MIGA installation site., Comment: Proceedings of SPIE Photonics Europe conference, Brussels (Belgium), 3-7 April 2016

Published

2016