*This research was supported in part by the National Science Foundation under Grant No. Our results are relevant for the characterization of compact binary mergers accompanied by EM counterparts. Lastly, we repeat the Poynting luminosity calculation, to analyze how the addition of matter changes the magnetic field amplification driven by the highly dynamical, strong gravitational field during the merger. But in addition to their job as relay molecules, second messengers serve to greatly amplify the strength of the signal. to target molecules in the cytosol and/or nucleus. We introduce next tidal effects to account for the coupling between matter and spacetime, present during the merger of a BNS system, and compare again our GW template with NR predictions. Second messengers are molecules that relay signals received at receptors on the cell surface such as the arrival of protein hormones, growth factors, etc. Cell signaling is the process in which a signaling molecule called ligand binds to a receptor protein in or on. We add the magnetic field and investigate the EM amplification by calculating the evolution of the Poynting luminosity during merger. Second messenger systems in signal transduction. We overlap the signal at the light ring (LR) and test our hybrid waveform against numerical relativity (NR) simulations. We start with a BBH system and calculate the GWs using the post-Newtonian (PN) formalism for the inspiral evolution and the Backwards-one-Body (BoB) model for the merger. We report on a novel implementation of fully analytical GW templates and electromagnetic (EM) radiation amplification during the merger of binary black holes (BBH) and binary neutron stars (BNS) using Python within the Jupyter Notebook. Although magnetized compact binary mergers are widely accepted as sources of GRBs, the mechanism behind jet formation is still unsettled. The simultaneous detection of both gravitational waves (GWs) and a short-duration gamma-ray burst (GRB) coined as GW170817/GRB 170817A, started the new field of Multi-Messenger Gravitational Wave Astronomy.
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