Your search keyword '"Piero Barbieri"' showing total 9 results

1. Intercontinental comparison of optical atomic clocks through very long baseline interferometry

Author

Ryuichi Ichikawa, J. Roda, Tetsuya Ido, Masanori Tsutsumi, Federico Perini, Filippo Levi, Giuseppe Maccaferri, Filippo Bregolin, Giampaolo Zacchiroli, Roberto Ricci, Julia Leute, Jun-ichi Komuro, Tetsuro Kondo, Rumi Takahashi, Marco Pizzocaro, Mauro Roma, Monia Negusini, Hideki Ujihara, Eiji Kawai, Nils Nemitz, Davide Calonico, E. Cantoni, Giancarlo Cerretto, Yoshihiro Okamoto, Mamoru Sekido, Gérard Petit, K. Takefuji, Kunitaka Namba, Claudio Bortolotti, Piero Barbieri, Cecilia Clivati, Alberto Mura, H. Hachisu, ITA, FRA, and JPN

Subjects

Physics, business.industry, General Physics and Astronomy, 01 natural sciences, Atomic clock, 010305 fluids & plasmas, 0103 physical sciences, Very-long-baseline interferometry, Fundamental physics, Broadband, Global Positioning System, Satellite, 010306 general physics, business, Optical metrology, Remote sensing, Radio astronomy

Abstract

The comparison of distant atomic clocks is foundational to international timekeeping, global positioning and tests of fundamental physics. Optical-fibre links allow the most precise optical clocks to be compared, without degradation, over intracontinental distances up to thousands of kilometres, but intercontinental comparisons remain limited by the performance of satellite transfer techniques. Here we show that very long baseline interferometry (VLBI), although originally developed for radio astronomy and geodesy, can overcome this limit and compare remote clocks through the observation of extragalactic radio sources. We developed dedicated transportable VLBI stations that use broadband detection and demonstrate the comparison of two optical clocks located in Italy and Japan separated by 9,000 km. This system demonstrates performance beyond satellite techniques and can pave the way for future long-term stable international clock comparisons. Very long baseline interferometry is used to compare two optical clocks located in Japan and Italy through the observation of extragalactic radio sources. This approach overcomes limitations of the performance of satellite transfer techniques.

Published

2020

2. Precise Frequency Transfer with Broadband Transportable VLBI Stations

Author

Filippo Levi, J. Roda, Masanori Tsutsumi, Roberto Ricci, Kunitaka Namba, Claudio Bortolotti, Hideki Ujihara, Rumi Takahashi, Hidekazu Hachisu, Mauro Roma, Piero Barbieri, Tetsuro Kondo, Kazuhiro Takefuji, Eiji Kawai, Cecilia Clivati, Mamoru Sekido, Jun-ichi Komuro, Davide Calonico, Giuseppe Maccaferri, Filippo Bregolin, Tetsuya Ido, Alberto Mura, Marco Pizzocaro, Yoshihiro Okamoto, Monia Negusini, Giancarlo Cerretto, Gérard Petit, Nils Nemitz, Giampaolo Zacchiroli, Julia Leute, Federico Perini, Ryuichi Ichikawa, and E. Cantoni

Subjects

Physics, Signal-to-noise ratio, Sampling (signal processing), Observatory, Broadband, Very-long-baseline interferometry, Radio frequency, Antenna (radio), Remote sensing, Group delay and phase delay

Abstract

For the aim to enable precise frequency transfer over earth radius scale distance, NICT developed a broadband VLBI system observing 3-14 GHz radio frequency range, and that was implemented in a pair of transportable 2.4m diameter VLBI stations and Kashima 34m diameter VLBI station. The small diameter VLBI stations installed in Medicina observatory of INAF (Italy) and NICT headquarters in Koganei (Japan) were used compare the atomic frequency standards. The poor sensitivity of VLBI observation with the small antenna pair was compensated by participation of the large diameter antenna for boosting the signal to noise ratio (SNR) of the VLBI observation. Owing to the broad observing frequency range, a few pico seconds precision of group delay is achieved on intercontinental baseline even with small diameter antenna. Advanced digital data acquisition with highspeed 16 GHz sampling enabled stable group delay measurement. A series of frequency transfer experiments was conducted during Oct. 2018 – Feb. 2019 by using the broadband VLBI system between ytterbium (Yb) optical lattice clock of INRiM (Italy) and strontium (Sr) lattice clock of NICT(Japan) separated by 9000km. The deviation of fractional frequency ratio between Yb and Sr was obtained by VLBI observation as y(Yb/Sr)=2.5(2.8)x10-16. The uncertainty in this experiment is evaluated not to be limited by the VLBI link itself, and further improvement is expected. Prospect of VLBI frequency link and uncertainty budget in VLBI observation is discussed in this report.

Published

2021

3. Intercontinental Comparison of Lattice Clocks Using a Broadband VLBI Technique

Author

Filippo Levi, Claudio Bortolotti, Ryuichi Ichikawa, Marco Pizzocaro, Mamoru Sekido, Federico Perini, G. Cerretto, M. Tsusumi, Filippo Bregolin, Eiji Kawai, Giuseppe Maccaferri, Tetsuya Ido, Davide Calonico, H. Ishijima, Hideki Ujihara, Monia Negusini, Nils Nemitz, Alberto Mura, Roberto Ricci, H. Hachisu, K. Takefuji, Piero Barbieri, Cecilia Clivati, Mauro Roma, ITA, and JPN

Subjects

Physics, Optical fiber, 010504 meteorology & atmospheric sciences, Clock signal, business.industry, 01 natural sciences, Frequency difference, law.invention, Radio observatory, Optics, law, Lattice (order), 0103 physical sciences, Broadband, Very-long-baseline interferometry, Optical clock, business, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences

Abstract

We performed a frequency comparison of lattice clocks in Tokyo and Torino for the first time using broadband VLBI technique. Two portable antennas with 2.4 m diameters were installed at NICT Koganei headquarters and INAF Medicina Radio Observatory, close to Bologna, Italy, realizing a VLBI network together with Kashima large-aperture antenna of 34 m diameter. The clock signal at INAF was evaluated by INRIM using an optical fiber link between Medicina and Torino. The fractional frequency difference that VLBI evaluated was consistent with the difference between two HM frequencies which were separately calibrated by a Sr lattice clock at NICT and a Yb lattice clock at INRIM.

Published

2019

4. Absolute frequency measurement of the 1S0 – 3P0 transition of 171Yb with a link to International Atomic Time

Author

Marco Pizzocaro, Benjamin Rauf, Davide Calonico, Filippo Levi, Piero Barbieri, and Filippo Bregolin

Subjects

Physics, Optical lattice, Traceability, International Atomic Time, Absolute frequency, General Engineering, Link (geometry), Frequency standard, 01 natural sciences, Computational physics, 010309 optics, Optical frequencies, 0103 physical sciences, International System of Units, 010306 general physics

Abstract

We report the absolute frequency measurement of the unperturbed optical clock transition 1S0–3P0 in 171Yb performed with an optical lattice frequency standard. Traceability to the International System of Units is provided by a link to International Atomic Time. The measurement result is 518 295 836 590 863.61(13) Hz with a relative standard uncertainty of , obtained operating our 171Yb optical frequency standard intermittently for 5 months. The 171Yb optical frequency standard contributes with a systematic uncertainty of .

Published

2019

5. Optical Atomic Clocks: From International Timekeeping to Gravity Potential Measurement

Author

Helen S. Margolis, Heiner Denker, Christian Voigt, Ludger Timmen, Jacopo Grotti, Silvio Koller, Stefan Vogt, Sebastian Häfner, Uwe Sterr, Christian Lisdat, Antoine Rolland, Fred N. Baynes, Michel Zampaolo, Pierre Thoumany, Marco Pizzocaro, Benjamin Rauf, Filippo Bregolin, Anna Tampellini, Piero Barbieri, Massimo Zucco, Giovanni A. Costanzo, Cecilia Clivati, Filippo Levi, and Davide Calonico

Subjects

High Energy Physics::Theory, Computer Science::Hardware Architecture, General Relativity and Quantum Cosmology

Abstract

We discuss the relation between atomic clocks and gravity from two perspectives: gravity potential measurements for optical clock comparisons and contributions to international timescales and, conversely, the measurement of gravity potential differences using optical clocks.

Published

2019

6. Geodesy and metrology with a transportable optical clock

Author

Ludger Timmen, Sebastian Häfner, Fred N. Baynes, Christian Lisdat, Christian Voigt, Massimo Zucco, Stefan Vogt, Heiner Denker, Uwe Sterr, Jacopo Grotti, Marco Pizzocaro, Filippo Levi, Helen S. Margolis, Benjamin Rauf, Giovanni Antonio Costanzo, Michel Zampaolo, Davide Calonico, Antoine Rolland, Anna Tampellini, Filippo Bregolin, Piero Barbieri, Cecilia Clivati, Silvio Koller, Pierre Thoumany, Physikalisch-Technische Bundesanstalt [Braunschweig] (PTB), X-ray Science Division (XSD), Leibniz Universität Hannover=Leibniz University Hannover, German Research Centre for Geosciences - Helmholtz-Centre Potsdam (GFZ), National Physical Laboratory [Teddington] (NPL), Laboratoire Souterrain de Modane (LSM - UMR 6417), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes [2016-2019] (UGA [2016-2019]), Istituto Nazionale di Ricerca Metrologica (INRiM), Leibniz Universität Hannover [Hannover] (LUH), and Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes [2016-2019] (UGA [2016-2019])-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)

Subjects

Physics, Optical lattice, Atomic Physics (physics.atom-ph), Lattice (group), General Physics and Astronomy, FOS: Physical sciences, Geodesy, 01 natural sciences, Atomic clock, Metrology, Physics - Atomic Physics, 010309 optics, Consistency (database systems), [SPI]Engineering Sciences [physics], Transformation (function), 0103 physical sciences, International System of Units, Instrumentation (computer programming), 010306 general physics

Abstract

The advent of novel measurement instrumentation can lead to paradigm shifts in scientific research. Optical atomic clocks, due to their unprecedented stability and uncertainty, are already being used to test physical theories and herald a revision of the International System of units (SI). However, to unlock their potential for cross-disciplinary applications such as relativistic geodesy, a major challenge remains. This is their transformation from highly specialized instruments restricted to national metrology laboratories into flexible devices deployable in different locations. Here we report the first field measurement campaign performed with a ubiquitously applicable $^{87}$Sr optical lattice clock. We use it to determine the gravity potential difference between the middle of a mountain and a location 90 km apart, exploiting both local and remote clock comparisons to eliminate potential clock errors. A local comparison with a $^{171}$Yb lattice clock also serves as an important check on the international consistency of independently developed optical clocks. This campaign demonstrates the exciting prospects for transportable optical clocks.

Published

2018

7. Multiple lasers stabilization on a single three color optical cavity

Author

Filippo Bregolin, Marco Pizzocaro, Filippo Levi, Pierre Thoumany, Gianmaria Milani, Davide Calonico, Benjamin Rauf, and Piero Barbieri

Subjects

Physics, Optical lattice, Sideband, business.industry, 02 engineering and technology, 021001 nanoscience & nanotechnology, Laser, 01 natural sciences, law.invention, 010309 optics, Wavelength, Laser linewidth, Optics, Light Shift, law, Optical cavity, 0103 physical sciences, Atom optics, 0210 nano-technology, business

Abstract

We designed and implemented a simple and robust optical system for the frequency stabilization of lasers at different wavelength, used for the cooling and trapping of atoms in a Yb optical lattice clock. We used a single ultra-stable cavity to lock the frequency of three different lasers at 399 nm, 556 nm and 759 nm exploiting the offset sideband locking technique, derived from the common Pound-Drever-Hall method. A linewidth of less than 300Hz is obtained at 556 nm with a fractional frequency stability of 3 × 10−14 at 1s. At 759 nm we measured a long term drift less than 20kHz per day, which is sufficient to keep the lattice light shift fractional uncertainty under 1 × 10−18. The system was tested by simultaneously locking the three lasers to the cavity and operating the clock without any significant reduction in number of atoms.

Published

2017

8. Multiple wavelength stabilization on a single optical cavity using the offset sideband locking technique

Author

Benjamin Rauf, Marco Pizzocaro, Filippo Levi, Davide Calonico, Gianmaria Milani, Piero Barbieri, Pierre Thoumany, and Filippo Bregolin

Subjects

Time delay and integration, Optical lattice, Laser stabilization, Materials science, Sideband, business.industry, Fabry-Perot, Laser, 01 natural sciences, Atomic and Molecular Physics, and Optics, law.invention, 010309 optics, Laser linewidth, Laser stabilization, Fabry-Perot, Atomic spectroscopy, Optics, Atomic spectroscopy, law, Optical cavity, Fiber laser, 0103 physical sciences, 010306 general physics, business, Fabry–Pérot interferometer

Abstract

We implemented a compact, robust, and stable device for simultaneous frequency stabilization of lasers with different wavelengths used for the cooling and trapping of Yb atoms in an optical lattice clock. The lasers at 399, 556, and 759 nm are locked to a single ultra-stable cavity using the offset sideband locking technique, a modified version of the Pound-Drever-Hall method. For the most demanding stabilization here, the 556 nm laser, this system exhibits a 300 Hz linewidth for an integration time of 80 ms. We observed a long-term drift of less than 20 kHz per day at 759 nm that is suitable for operating the lattice laser with a light shift uncertainty below 1×10sup-18/sup. We successfully tested the system for operating the clock during a typical working day by simultaneously locking the three lasers to the cavity.

Published

2017

9. Spectral purity transfer with 5 × 10−17 instability at 1 s using a multibranch Er:fiber frequency comb.

Author

Piero Barbieri, Cecilia Clivati, Marco Pizzocaro, Filippo Levi, and Davide Calonico

Published

2019