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Devenoges, Laurent

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Devenoges, Laurent
Affiliation principale
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Ancien.ne collaborateur.trice
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https://libra.unine.ch/handle/123456789/489

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  • Publication
    Accès libre
    Status and prospect of the Swiss continuous Cs fountain FoCS-2
    Jallageas, Antoine 
    ;
    Devenoges, Laurent 
    ;
    Petersen, Michael
    ;
    Morel, Jacques
    ;
    Bernier, Laurent-Guy
    ;
    Thomann, Pierre 
    ;
    Südmeyer, Thomas 
    The continuous cesium fountain clock FoCS-2 at METAS presents many unique characteristics and challenges in comparison with standard pulsed fountain clocks. For several years FoCS-2 was limited by an unexplained frequency sensitivity on the velocity of the atoms, in the range of 140 · 10-15. Recent experiments allowed us to identify the origin of this problem as undesirable microwave surface currents circulating on the shield of the coaxial cables that feed the microwave cavity. A strong reduction of this effect was obtained by adding microwave absorbing coatings on the coaxial cables and absorbers inside of the vacuum chamber. This breakthrough opens the door to a true metrological validation of the fountain. A series of simulation tools have already been developed and proved their efficiency in the evaluation of some of the uncertainties of the continuous fountain. With these recent improvements, we are confident in the future demonstration of an uncertainty budget at the 10-15 level and below.
  • Publication
    Accès libre
    Measurement of the magnetic field profile in the atomic fountain clock FoCS-2 using Zeeman spectroscopy
    Devenoges, Laurent 
    ;
    Di Domenico, Gianni 
    ;
    Stefanov, André
    ;
    Jallageas, Antoine 
    ;
    Morel, Jacques
    ;
    Südmeyer, Thomas 
    ;
    Thomann, Pierre 
    We report the evaluation of the second-order Zeeman shift in the continuous atomic fountain clock FoCS-2. Because of its continuous operation and geometrical constraints, the methods used in pulsed fountains are not applicable. We use here time-resolved Zeeman spectroscopy to probe the magnetic field profile in the clock. Pulses of ac magnetic excitation allow us to spatially resolve the Zeeman frequency and to evaluate the Zeeman shift with a relative uncertainty smaller than 5 × 10−16.
  • Publication
    Accès libre
    First investigation of the noise and modulation properties of the carrier-envelope offset in a modelocked semiconductor laser
    Brochard, Pierre 
    ;
    Jornod, Nayara 
    ;
    Schilt, Stephane 
    ;
    Wittwer, Valentin 
    ;
    Hakobyan, Sargis 
    ;
    Waldburger, Dominik
    ;
    Link, Sandro M
    ;
    Alfieri, Cesare G. E
    ;
    Golling, Matthias
    ;
    Devenoges, Laurent 
    ;
    Morel, Jacques
    ;
    Keller, Ursula
    ;
    Südmeyer, Thomas. Laboratoire Temps-Fréquence, Université de Neuchâtel, Switzerland
    We present the first characterization of the noise properties and modulation response of the carrier-envelope offset (CEO) frequency in a semiconductor modelocked laser. The CEO beat of an optically-pumped vertical external-cavity surface-emitting laser (VECSEL) at 1030 nm was characterized without standard ƒ-to-2ƒ interferometry. Instead, we used an appropriate combination of signals obtained from the modelocked oscillator and an auxiliary continuous-wave laser to extract information about the CEO signal. The estimated linewidth of the free-running CEO beat is approximately 1.5 MHz at 1-s observation time, and the feedback bandwidth to enable a tight CEO phase lock to be achieved in a future stabilization loop is in the order of 300 kHz. We also characterized the amplitude and phase of the pump current to CEO-frequency transfer function, which showed a 3-dB bandwidth of ∼300 kHz for the CEO frequency modulation. This fulfills the estimated required bandwidth and indicates that the first self-referenced phase-stabilization of a modelocked semiconductor laser should be feasible in the near future.