27 research outputs found

    Laser Cooling of Molecular Anions

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    We propose a scheme for laser cooling of negatively charged molecules. We briefly summarise the requirements for such laser cooling and we identify a number of potential candidates. A detailed computation study with C_2−\_2^-, the most studied molecular anion, is carried out. Simulations of 3D laser cooling in a gas phase show that this molecule could be cooled down to below 1 mK in only a few tens of milliseconds, using standard lasers. Sisyphus cooling, where no photo-detachment process is present, as well as Doppler laser cooling of trapped C_2−\_2^-, are also simulated. This cooling scheme has an impact on the study of cold molecules, molecular anions, charged particle sources and antimatter physics

    1S-3S cw spectroscopy of hydrogen/deuterium atom

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    We study the 1S-3S two-photon transition of hydrogen in a thermal atomic beam, using a homemade cw laser source at 205 nm. The experimental method is described, leading in 2017 to the measurement of the 1S-3S transition frequency in hydrogen atom with a relative uncertainty of 9×10−139 \times 10^{-13}. This result contributes to the "proton puzzle" resolution but is in disagreement with the ones of some others experiments. We have recently improved our setup with the aim of carrying out the same measurement in deuterium. With the improved detection system, we have observed a broadened fluorescence signal, superimposed on the narrow signal studied so far, and due to the stray accumulation of atoms in the vacuum chamber. The possible resulting systematic effect is discussed

    Experimental perspectives on the matter-antimatter asymmetry puzzle: developments in electron EDM and antihydrogen experiments

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    In the search for clues to the matter-antimatter puzzle, experiments with atoms or molecules play a particular role. These systems allow measurements with very high precision, as demonstrated by the unprecedented limits down to 10−3010^{-30} e.cm on electron EDM using molecular ions, and relative measurements at the level of 10−1210^{-12} in spectroscopy of antihydrogen atoms. Building on these impressive measurements, new experimental directions offer potentials for drastic improvements. We review here some of the new perspectives in those fields and their associated prospects for new physics searches

    A compact 20-pass thin-disk multipass amplifier stable against thermal lensing effects and delivering 330 mJ pulses with M2<1.17\bf{M^2 < 1.17}

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    We report on an Yb:YAG thin-disk multipass amplifier delivering 50 ns long pulses at a central wavelength of 1030 nm with an energy of 330 mJ at a repetition rate of 100 Hz. The beam quality factor at the maximum energy was measured to be M2=1.17\text{M}^2 = 1.17. The small signal gain is 20, and the gain at 330 mJ was measured to be 6.9. The 20-pass amplifier is designed as a concatenation of stable resonator segments in which the beam is alternately Fourier transformed and relay-imaged back to the disk by a 4f-imaging optical scheme stage. The Fourier transform propagation makes the output beam robust against spherical phase front distortions, while the 4f-stage is used to compensate the thermal lens of the thin-disk and to reduce the footprint of the amplifier

    Manipulation et refroidissement laser de l'antimatiÚre, au sein de l'expérience AEgIS

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    My Ph.D project took place within the AEgIS collaboration, one of the antimatter experiments at the CERN. The final goal of the experiment is to perform a gravity test on a cold antihydrogen (Hbar) beam. AEgIS proposes to create such a cold Hbar beam based on a charge exchange reaction between excited Rydberg Positronium (Ps) and cold trapped antiprotons: 〖Ps〗^* + pbar → (H^*)⁻ + e⁻. Studying the Ps physics is crucial for the experiment, and requires adapted lasers systems. During this Ph.D, my primary undertaking was the responsibility for the laser systems in AEgIS. To excite Ps atom up to its Rydberg states (≃20) in presence of a high magnetic field (1 T), two broadband pulsed lasers have been developed. We realized the first laser excitation of the Ps into the n=3 level, and demonstrated an efficient optical path to reach the Rydberg state n=16-17. These results, obtained in the vacuum test chamber and in absence of strong magnetic field, reach a milestone toward the formation of antihydrogen in AEgIS, and the immediate next step for us is to excite Ps atoms inside our 1 T trapping apparatus, where the formation of antihydrogen will take place. However, even once this next step will be successful, the production rate of antihydrogen atoms will nevertheless be very low, and their temperature much higher than could be wished. During my Ph.D, I have installed further excitation lasers, foreseen to perform fine spectroscopy on Ps atoms and that excite optical transitions suitable for a possible Doppler cooling. I have carried out theoretical studies and simulations to determine the proper characteristics required for a cooling laser system. The transverse laser cooling of the Ps beam will enhance the overlap between the trapped antiprotons plasma and the Ps beam during the charge-exchange process, and therefore drastically improve the production rate of antihydrogen. The control of the compression and cooling of the antiproton plasma is also crucial for the antihydrogen formation. During the beam-times of 2014 and 2015, I participated in the characterization and optimization our catching and manipulation procedures to reach highly compressed antiproton plasma, in repeatable conditions. Another project in AEgIS I took part aims to improve the formation rate of ultracold antihydrogen, by studying the possibility of a sympathetically cooling of the antiprotons using a laser-cooled anion plasma. I investigated some laser cooling schemes on the C₂⁻ molecular anions, and the simulations are promising. I actively contribute to the commissioning of the test apparatus at CERN to carry on the trials of laser cooling on the C₂⁻ species. If successful, this result will not only be the first cooling of anions by laser, but will open the way to a highly efficient production of ultracold antihydrogen atoms.Ma thĂšse s’est dĂ©roulĂ©e dans le cadre de la collaboration AEgIS, une des expĂ©riences Ă©tudiant l’antimatiĂšre au CERN. L’objectif final est de mesurer l’effet de la gravitĂ© sur un faisceau froid d’antihydrogĂšne (Hbar). AEgIS se propose de crĂ©er les Hbar froids par Ă©change de charges entre un atome de Positronium (Ps) excitĂ© (Ă©tat de Rydberg) et un antiproton piĂ©gĂ© : 〖Ps〗^*+ pbar → (H^*)⁻ + e⁻. L’étude de la physique du Ps est cruciale pour AEgIS, et demande des systĂšmes lasers adaptĂ©s. Pendant ma thĂšse, ma premiĂšre tĂąche a Ă©tĂ© de veiller au bon fonctionnement des systĂšmes lasers de l’expĂ©rience. Afin d’exciter le positronium jusqu’à ses Ă©tats de Rydberg (≃20) en prĂ©sence d’un fort champ magnĂ©tique (1 T), deux lasers pulsĂ©s spectralement larges ont Ă©tĂ© spĂ©cialement conçu. Nous avons rĂ©alisĂ© la premiĂšre excitation par laser du Ps dans son niveau n=3, et prouvĂ© une excitation efficace du nuage de Ps vers les niveaux de Rydberg n=16-17. Ces mesures, rĂ©alisĂ©es dans la chambre Ă  vide de test d’AEgIS, Ă  tempĂ©rature ambiance et pour un faible champ magnĂ©tique environnant, sont la premiĂšre Ă©tape vers la formation d’antihydrogĂšne. Le prochain objectif est de rĂ©pĂ©ter ces rĂ©sultats dans l’enceinte du piĂšge Ă  1 T, oĂč les antihydrogĂšnes seront formĂ©s. Pour autant, malgrĂ© l’excitation Rydberg des Ps pour accroĂźtre la section efficace de collision, la production d’antihydrogĂšne restera faible, et la tempĂ©rature des H bar formĂ©s sera trop Ă©levĂ©e pour toute mesure de gravitĂ©. Pendant ma thĂšse, j’ai installĂ© au CERN un autre systĂšme laser prĂ©vu pour pratiquer une spectroscopie prĂ©cise des niveaux de Rydberg du Ps. Ce systĂšme excite des transitions optiques qui pourraient convenir Ă  un refroidissement Doppler : la transition n=1 ↔ n=2. J’ai Ă©tudiĂ© la possibilitĂ© d’un tel refroidissement, en procĂ©dant Ă  des simulations poussĂ©es pour dĂ©terminer les caractĂ©ristiques d’un systĂšme laser adaptĂ© La focalisation du nuage de Ps grĂące au refroidissement des vitesses transverses devrait accroitre le recouvrement des positroniums avec les antiprotons piĂ©gĂ©s, et ainsi augmenter grandement la production d’Hbar. Le contrĂŽle du refroidissement et de la compression du plasma d’antiprotons est aussi essentiel pour la formation des antihydrogĂšnes. Pendant les temps de faisceaux d’antiprotons de 2014 et 2015, j’ai contribuĂ© Ă  la caractĂ©risation et l’optimisation des procĂ©dures pour attraper et manipuler les antiprotons, afin d’atteindre des plasmas trĂšs denses, et ce, de façon reproductible. Enfin, j’ai participĂ© activement Ă  l’élaboration d’autre projet Ă  l’étude AEgIS, qui vise aussi Ă  augmenter la production d’antihydrogĂšne : le projet d’un refroidissement sympathique des antiprotons, en utilisant un plasma d’anions refroidis par laser. J’ai Ă©tudiĂ© la possibilitĂ© de refroidir l’ion molĂ©culaire C₂⁻, et les rĂ©sultats de simulations sont encourageants. Nous sommes actuellement en train de dĂ©velopper au CERN le systĂšme expĂ©rimental qui nous permettra de faire les premiers tests de refroidissement sur le C₂⁻. Si couronnĂ© de succĂšs, ce projet ne sera pas seulement le premier rĂ©sultat de refroidissement par laser d’anions, mais ouvrira aussi les portes Ă  une production efficace d’antihydrogĂšnes froids

    Positronium laser cooling in a magnetic field

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    We study realistic 3D laser cooling of positronium (Ps) in the presence of a magnetic field. Triplet and singlet states mixing due to the magnetic field, and dynamical Stark effect, generally produce higher annihilation rates than in the zero-field case. 3D cooling is efficient only at very low field Bâ‰Č50mT and at high field values BâȘ†0.7T. Near 100ns long laser pulses, spectrally broad enough to cover most of the Ps Doppler profile and with energy in the mJ range, are required to cool Ps. Simulations based on full diagonalization of the Stark and Zeeman Hamiltonian and a kinetic Monte Carlo algorithm exactly solving the rate equations indicate that an efficient cooling (typically from 300K down to below 50K) is possible even in a magnetic field. We also propose 3D moving molasses cooling that can produce a well-defined monochromatic Ps beam useful for applications

    1S–3S cw spectroscopy of hydrogen/deuterium atom

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    International audienceWe study the 1S-3S two-photon transition of hydrogen in a thermal atomic beam, using a homemade cw laser source at 205 nm. The experimental method is described, leading in 2017 to the measurement of the 1S-3S transition frequency in hydrogen atom with a relative uncertainty of 9 × 10 −13. This result contributes to the "proton puzzle" resolution but is in disagreement with the ones of some others experiments. We have recently improved our setup with the aim of carrying out the same measurement in deuterium. With the improved detection system, we have observed a broadened fluorescence signal, superimposed on the narrow signal studied so far, and due to the stray accumulation of atoms in the vacuum chamber. The possible resulting systematic effect is discussed

    GRASIAN: towards the first demonstration of gravitational quantum states of atoms with a cryogenic hydrogen beam

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    At very low energies, a light neutral particle above a horizontal surface can experience quantum reflection. The quantum reflection holds the particle against gravity and leads to gravitational quantum states (GQs). So far, GQs were only observed with neutrons as pioneered by Nesvizhevsky and his collaborators at ILL. However, the existence of GQs is predicted also for atoms. The GRAsIAN collaboration pursues the first observation and studies of GQs of atomic hydrogen. We propose to use atoms in order to exploit the fact that orders of magnitude larger fluxes compared to those of neutrons are available. Moreover, recently the q -BOUNCE collaboration, performing GQs spectroscopy with neutrons, reported a discrepancy between theoretical calculations and experiment which deserves further investigations. For this purpose, we set up a cryogenic hydrogen beam at 6 K. We report on our preliminary results, characterizing the hydrogen beam with pulsed laser ionization diagnostics at 243 nm.ISSN:1434-6060ISSN:1434-607

    Pound–Drever–Hall locking scheme free from Trojan operating points

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    The Pound–Drever–Hall (PDH) technique is a popular method for stabilizing the frequency of a laser to a stable optical resonator or, vice versa, the length of a resonator to the frequency of a stable laser. We propose a refinement of the technique yielding an “infinite” dynamic (capture) range so that a resonator is correctly locked to the seed frequency, even after large perturbations. The stable but off-resonant lock points (also called Trojan operating points), present in conventional PDH error signals, are removed by phase modulating the seed laser at a frequency corresponding to half the free spectral range of the resonator. We verify the robustness of our scheme experimentally by realizing an injection-seeded Yb:YAG thin-disk laser. We also give an analytical formulation of the PDH error signal for arbitrary modulation frequencies and discuss the parameter range for which our PDH locking scheme guarantees correct locking. Our scheme is simple as it does not require additional electronics apart from the standard PDH setup and is particularly suited to realize injection-seeded lasers and injection-seeded optical parametric oscillators.ISSN:0034-6748ISSN:1089-762
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