Abstract
The second-generation interferometric gravitational wave detectors, currently under construction are expected to make their first detections within this decade. This will firmly establish gravitational wave physics as an empirical science, and will open up a new era in astrophysics, cosmology, and fundamental physics. Already with the first detections, we will be able to, among other things, establish the nature of short-hard gamma ray bursts, definitively confirm the existence of black holes, measure the Hubble constant in a completely independent way, and for the first time gain access to the genuinely strong-field dynamics of gravity. Hence, it is time to consider the longer-term future of this new field. The Einstein Telescope (ET) is a concrete conceptual proposal for a third-generation gravitational wave observatory, which will be ~ 10 times more sensitive in strain than the second-generation detectors. This will give access to sources at cosmological distances, with a correspondingly higher detection rate. We have given an overview of the science case for ET, with a focus on what can be learned from signals emitted by coalescing compact binaries. Third-generation observatories will allow us to map the coalescence rate out to redshifts z ~ 3, determine the mass functions of neutron stars and black holes, and perform precision measurements of the neutron star equation of state. ET will enable us to study the large-scale structure and evolution of the Universe without recourse to a cosmic distance ladder. Finally, we have discussed how it will allow for high-precision measurements of strong-field, dynamical gravity.
Highlights
A network of second-generation, kilometer scale interferometric gravitational wave detectors is currently under construction: Advanced LIGO in the US [1], Advanced Virgo in Europe [2], and KAGRA in Japan [3]; a further large interferometer might be built in India [4]
More recent work by Taylor and Gair [44] based on method (ii), which allows the use of all BNS inspiral events seen in gravitational waves, has demonstrated that a network of Einstein Telescope (ET) would be able to beat the predicted accuracy of the future supernova surveys
Summary The advanced interferometric gravitational wave detectors that are currently being built have the potential to settle important scientific questions: What is the local coalescence rate, and what does this imply for our understanding of the evolution of massive stars? What is the nature of short-hard gamma ray bursts? Do black holes really exist, or is there some alternative kind of very compact object? What does the equation of state of neutron stars approximately look like? Are estimates of the present-day expansion of the Universe correct? Is general relativity really the correct theory of gravity in the strong-field, dynamical regime?
Summary
A network of second-generation, kilometer scale interferometric gravitational wave detectors is currently under construction: Advanced LIGO in the US [1], Advanced Virgo in Europe [2], and KAGRA in Japan [3]; a further large interferometer might be built in India [4]. Fisher matrix results indicate that in the gravitational wave frequency range 10 Hz - 450 Hz, with the advanced detector network and a single high-SNR source we will only have access to the stiffest EOS leading to the largest values of the deformability λ.
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