The recent direct observation of gravitational waves from a binary black-hole merger has marked the beginning of gravitational-wave astronomy. To enable a continuous stream of detections with a high signal-to-noise ratio, upcoming generations of gravitational-wave detectors, which are based on the principle of laser interferometry, will aim at an increase of strain sensitivity by at least an order of magnitude. Through most of the detection band, the limiting noise sources are given by thermal noise in the mirror coatings and substrates, as well as quantum noise of the laser light field. Future detectors foresee a change to crystalline silicon as mirror material and operation at cryogenic temperatures. This will need to be accompanied by a change in laser wavelength to around 2µm, from the currently used 1µm. At the same time, squeezed states of light have been successfully shown to reduce the quantum noise in gravitational-wave detectors. Combining these two advancements is therefore a major step towards a successful era of gravitational-wave astronomy. So far, laser development at around 2µm has been driven by LIDAR and medical applications, therefore little experience exists with the demanding stability requirements for high-power lasers in gravitational-wave detectors. Furthermore, squeezed light has not been demonstrated at 2µm, and photo detectors with a near-unity quantum efficiency - so as to not destroy the fragile nonclassical correlations in the squeezed field - are not yet available.The project team will develop a complete solution for 2µm laser technology aimed at gravitational-wave detection that is solely based on degenerate parametric down-conversion of the existing highly stable 1064nm laser sources. Within this project, we will develop a squeezed-light source at 2.128µm, demonstrating for the first time that this wavelength is compatible with advanced quantum-noise reduction techniques. In addition, we will show compensation of detection loss by optical parametric amplification, partly removing the need for photo detectors with almost perfect quantum efficiency. The results of this work will thus play a significant role in planning and enabling future gravitational-wave detectors, pushing the boundaries of the observable universe.

DFG Programme Research Grants

Major Instrumentation Hochstabiler Dauerstrichlaser, 2W bei 1064nm

Instrumentation Group 5700 Festkörper-Laser

Ehemaliger Antragsteller Dr. Sebastian Steinlechner, until 7/2019