The most precise measurement tools of humankind are equipped with ultra-stable lasers. State-of-the-art laser stabilization techniques are based on external cavities, that are limited by noise originated in the coatings of the cavity mirrors. Microstructured mirror coatings (so-called meta-mirrors) are a promising technology to overcome the limitations of coating noise and therewith pave the way towards next-generation ultra-stable lasers. We present experimental realization of a 12,000-finesse optical cavity based on one low-noise meta-mirror. The use of the mirrors studied here in cryogenic silicon cavities represents an order of magnitude reduction in the current limiting mirror noise, such that the stability limit due to fundamental noise can be reduced to 5 × 10−18.
The precision of many applications in high-precision metrology involving optical cavities is limited by the Brownian thermal noise of mirror coatings. Meta-mirrors are promising to overcome current noise limitations. In this contribution, we demonstrate a meta-etalon combining a meta-mirror with a conventional multilayer mirror to enhance the maximum reflectivity of the meta-mirror while maintaining low thermal noise. By this, we achieve a cavity finesse of 11.500, more than a factor of 10 larger than the maximum achieved with standalone meta-mirrors.
The most precise measurement tools of humankind are equipped with ultra-stable lasers. State-of-the-art laser stabilization techniques are based on external cavities, that are limited by noise originated in the coatings of the cavity mirrors. Microstructured mirror coatings (so-called meta-mirrors) are a promising technology to overcome the limitations of coating noise and therewith pave the way towards next-generation ultra-stable lasers. We present the first experimental realization of a 10,000-finesse optical cavity based on a low-noise meta-mirror, representing a milestone in this field. The symbiosis of the presented mirror technology with silicon cavity spacers will result in a 5×10−18 laser stability, which is an order of magnitude improvement.
Ion traps are a promising platform for the realisation of high-performance quantum computers. To enable the future scalability of these systems, integrated photonic solutions for guiding and manipulating the laser light at chip level are a major step. Such passive optical components offer the great advantage of providing beam radii in the μm range at the location of the ions without increasing the number of bulk optics. Different wavelengths, from UV to NIR, as well as laser beam properties, such as angle or polarisation, are required for different cooling and readout processes of ions. We present simulation results for different optical photonic components, such as grating outcouplers or waveguide splitters and their applications on ion trap chips. Furthermore, we will introduce the experimental setup for the optical characterisation of the fabricated structures.
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