Abstract
Multimessenger observations may hold the key to learn about the most energetic sources in the universe. The recent construction of large scale observatories opened new possibilities in testing non thermal cosmic processes with alternative probes, such as high energy neutrinos and gravitational waves. We propose to combine information from gravitational wave detections, neutrino observations and electromagnetic signals to obtain a comprehensive picture of some of the most extreme cosmic processes. Gravitational waves are indicative of source dynamics, such as the formation, evolution and interaction of compact objects. These compact objects can play an important role in astrophysical particle acceleration, and are interesting candidates for neutrino and in general high-energy astroparticle studies. In particular we will concentrate on the most promising gravitational wave emitter sources: compact stellar remnants. The merger of binary black holes, binary neutron stars or black hole-neutron star binaries are abundant gravitational wave sources and will likely make up the majority of detections. However, stellar core collapse with rapidly rotating core may also be significant gravitational wave emitter, while slower rotating cores may be detectable only at closer distances. The joint detection of gravitational waves and neutrinos from these sources will probe the physics of the sources and will be a smoking gun of the presence of hadrons in these objects which is still an open question. Conversely, the non-detection of neutrinos or gravitational waves from these sources will be fundamental to constrain the hadronic content.
Highlights
With the contemporary operation of the IceCube and Antares, Advanced LIGO and Advanced Virgo facilities, we are able to observe the universe using two new, distinct astrophysical messengers
The realization of generation high energy detectors like CTA for TeV photons, KM3Net and IceCube-Gen2 for higher energy neutrinos and the improving sensitivity of gravitational waves (GWs) detectors will open a new era in multi-messenger astrophysics that we propose to exploit
The study of common sources of GWs, neutrinos and gamma-rays requires a broad understanding of the emission processes and detection technique
Summary
With the contemporary operation of the IceCube and Antares, Advanced LIGO and Advanced Virgo facilities, we are able to observe the universe using two new, distinct astrophysical messengers. The realization of generation high energy detectors like CTA for TeV photons, KM3Net and IceCube-Gen for higher energy neutrinos and the improving sensitivity of GW detectors will open a new era in multi-messenger astrophysics that we propose to exploit. Beyond neutrinos, another major pillar of multi-messenger probes are GWs. Advanced LIGO [5] recently made the first direct detection of GWs [6]. No significant temporally and directionally coincident neutrinos were found by these searches
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Disclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.