Abstract
The discovery of gravitational waves resulting from the merger of two massive black holes (GW150914) has revolutionized our view of merging compact binaries. Recently, the Swope Supernova Survey of the optical counterpart of a gravitational wave event in the NGC 4993 galaxy, GW170817, emanating from the merger of two neutron stars, has triggered a lot of research work. Emphasis has been on comparing the existing theoretical models with the observational data, allowing for the prospect of an even more stringent test of general relativity. The afterglow of this event was observed in a wide range of wavelengths extending from radio waves to gamma rays. In this work, we first explore the evolutionary pathways of compact binary systems following the in-spiral, merger, and ring down sequence. We then proceed to discuss the processes leading to the production of gravitational waves and electromagnetic emission resulting from the merger of compact objects, particularly neutron star binaries and neutron star-black hole systems. We construct a basic inventory of the energy released during the merger of compact binaries in all bands of the electromagnetic spectrum with emphasis on gamma-ray burst emission. The constraints on certain wavelength emissions, such as gamma-ray bursts, are discussed in terms of orbital dynamical instabilities, energy transfer processes, and possible jet orientations with respect to the observer. Finally, we explore the futuristic perspective of the impact of gravitational waves detection on our understanding of the working of the universe.
Highlights
Gravitational waves are ripples in the fabric of spacetime generated by accelerating masses
The first generation of detected gravitational waves emanating from the merger of compact binaries involved five events, four of which were produced by the merger of binary black holes and only one was produced by the merger of neutron stars
This is basically because black hole binaries are more massive than neutron star binaries and, the strain associated with gravitational waves resulting from their merger can be detected to large distances
Summary
Gravitational waves are ripples in the fabric of spacetime generated by accelerating masses. Primordial gravitational waves were predicted by the theory of inflation during the very early universe when spacetime experienced a short period faster than light expansion This background signal is very weak to be observed by current instruments. An observer of a GW will discover that spacetime is distorted by the effect of strain This effect will produce a rhythmic increase and decrease of distances between objects at the frequency of the wave, and its magnitude decreases in proportion to the inverse square law from the source. This effect when measured on Earth after propagating through astronomical distances is extremely small, having strains of the order 10−21. Azzam last part of this paper we explore the futuristic perspective of gravitational waves and their impact on new horizons in astrophysics
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