A high-stability semiconductor laser system for a 88Sr-based optical lattice clock

Abstract We describe a frequency-stabilized diode laser at 698 nm used for high-resolution spectroscopy of the 1$ S_{0} $–3$ P_{0} $ strontium clock transition. For the laser stabilization we use state-of-the-art symmetrically suspended optical cavities optimized for very low thermal noise at room t...
Ausführliche Beschreibung

Abstract We describe a frequency-stabilized diode laser at 698 nm used for high-resolution spectroscopy of the 1$ S_{0} $–3$ P_{0} $ strontium clock transition. For the laser stabilization we use state-of-the-art symmetrically suspended optical cavities optimized for very low thermal noise at room temperature. Two-stage frequency stabilization to high-finesse optical cavities results in measured laser frequency noise about a factor of three above the cavity thermal noise between 2 Hz and 11 Hz. With this system, we demonstrate high-resolution remote spectroscopy on the 88Sr clock transition by transferring the laser output over a phase noise-compensated 200-m-long fiber link between two separated laboratories. Our dedicated fiber link ensures a transfer of the optical carrier with frequency stability of 7×$ 10^{−18} $ after 100 s integration time, which could enable the observation of the strontium clock transition with an atomic Q of $ 10^{14} $. Furthermore, with an eye toward the development of transportable optical clocks, we investigate how the complete laser system (laser+optics+cavity) can be influenced by environmental disturbances in terms of both short- and long-term frequency stability. Ausführliche Beschreibung