Reprint

Present and Future of Gravitational Wave Astronomy

Edited by
September 2022
428 pages
  • ISBN978-3-0365-5225-5 (Hardback)
  • ISBN978-3-0365-5226-2 (PDF)

This is a Reprint of the Special Issue Present and Future of Gravitational Wave Astronomy that was published in

Physical Sciences
Summary

The first detection on Earth of a gravitational wave signal from the coalescence of a binary black hole system in 2015 established a new era in astronomy, allowing the scientific community to observe the Universe with a new form of radiation for the first time. More than five years later, many more gravitational wave signals have been detected, including the first binary neutron star coalescence in coincidence with a gamma ray burst and a kilonova observation.

The field of gravitational wave astronomy is rapidly evolving, making it difficult to keep up with the pace of new detector designs, discoveries, and astrophysical results.

This Special Issue is, therefore, intended as a review of the current status and future directions of the field from the perspective of detector technology, data analysis, and the astrophysical implications of these discoveries.

Rather than presenting new results, the articles collected in this issue will serve as a reference and an introduction to the field. This Special Issue will include reviews of the basic properties of gravitational wave signals; the detectors that are currently operating and the main sources of noise that limit their sensitivity; planned upgrades of the detectors in the short and long term; spaceborne detectors; a data analysis of the gravitational wave detector output focusing on the main classes of detected and expected signals; and implications of the current and future discoveries on our understanding of astrophysics and cosmology.

Format
  • Hardback
License and Copyright
© 2022 by the authors; CC BY-NC-ND license
Keywords
LIGO; Virgo; KAGRA; gravitational waves; detector characterization; data quality; noise mitigation; seismic noise; Newtonian noise; seismic isolation system; noise subtraction; gravitational waves; DECIGO; thermal noise; quantum noise; diffraction loss; gravitational waves; interferometers; ground based gravitational-wave detector; Advanced Virgo; gravitational waves; gravitational-wave backgrounds; stochastic gravitational-wave backgrounds; stochastic searches of gravitational waves; gravitational-wave laser interferometers; pulsar timing arrays; gravitational wave detectors; optomechanics; low-noise high-power laser interferometry; calibration; interferometer; gravitational wave; astrophysics; laser metrology; gravitational waves; squeezed states; quantum optics; interferometer; quantum noise; gravitational wave detector; laser interferometer; cryogenics; underground; gravitational waves; einstein telescope; seismic noise; newtonian noise; thermal noise; coating noise; silicon; suspensions; cryogenics; payload; cryostat; gravitational waves; core-collapse supernova; future detectors; continuous gravitational waves; neutron stars; dark matter; LIGO; Virgo; KAGRA; gravitational-wave astrophysics; stars; black holes; stellar evolution; binary stars; stellar dynamics; gravitational waves; laser interferometers; black holes; neutron stars; n/a