Francesco Maione scite author profile

We present three-dimensional simulations of the dynamics of binary neutron star (BNS) mergers from the late stage of the inspiral process up to ∼ 20 ms after the system has merged, either to form a hyper-massive neutron star (NS) or a rotating black hole (BH). We investigate five equalmass models of total gravitational mass 2.207, 2.373, 2.537, 2.697 and 2.854 M , respectively; and four unequal mass models with M ADM 2.53 M and q 0.94, 0.88, 0.83, and 0.77 (whereis the mass ratio). We use a semi-realistic equation of state (EOS), namely the seven-segment piece-wise polytropic SLyPP with a thermal component given by Γ th = 1.8. We have also compared the resulting dynamics (for one model) using both, the BSSN-NOK and CCZ4 methods for the evolution of the gravitational sector, and also different reconstruction methods for the matter sector, namely PPM, WENO and MP5. Our results show agreement and high resolution, but superiority of BSSN-NOK supplemented by WENO reconstruction at lower resolutions.One of the important characteristics of the present investigation is that for the first time, it has been done using only publicly available open source software: the Einstein Toolkit code, deployed for the dynamical evolution; and the LORENE code, for the generation of the initial models. All of the source code and parameters used for the simulations have been made publicly available. This not only makes it possible to re-run and re-analyze our data, but also enables others to directly build upon this work for future research.

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Spectral analysis of gravitational waves from binary neutron star merger remnants

Maione

Pietri

Feo

et al. 2017

Phys. Rev. D

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In this work we analyze the gravitational wave signal from hyper-massive neutron stars formed after the merger of binary neutron star systems, focusing on its spectral features. The gravitational waves signal are extracted from numerical relativity simulations of models already considered in [1][2][3], and allow us to study the effect of the total baryonic mass of such systems (from 2.4M to 3M ), the mass ratio (up to q = 0.77) and the neutron star equation of state, both in equal and highly unequal mass binaries. We use the peaks we find in the gravitational spectrum as independent test of already published hypotheses of their physical origin and empirical relations linking them with the characteristics of the merging neutron stars. In particular, we highlight the effects of the mass-ratio, which in the past was often neglected. We also analyze the temporal evolution of the emission frequencies. Finally, we introduce a modern variant of the Prony's method to analyze the Gravitational Wave post-merger emission as a sum of complex exponentials, trying to overcome some drawbacks of both Fourier spectra and least-square fitting. Overall, the spectral properties of the post-merger signal observed in our simulation are in agreement with those proposed by other groups. More specificaly, we find that analysis of [4] is particularly effective for binaries with very low masses or with small mass ratio and that the mechanical toy model of [5] provides a comprehensive and accurate description of the early stages of the post-merger.

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Binary neutron star merger simulations with different initial orbital frequency and equation of state

Maione

Pietri

Feo

et al. 2016

Class. Quantum Grav.

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We present results from three-dimensional general relativistic simulations of binary neutron star coalescences and mergers using public codes. We considered equal mass models where the baryon mass of the two Neutron Stars (NS) is 1.4M , described by four different equations of state (EOS) for the cold nuclear matter (APR4, SLy, H4, and MS1; all parametrized as piecewise polytropes). We started the simulations from four different initial interbinary distances (40, 44.3, 50, and 60 km), including up to the last 16 orbits before merger. That allows to show the effects on the gravitational wave phase evolution, radiated energy and angular momentum due to: the use of different EOSs, the orbital eccentricity present in the initial data and the initial separation (in the simulation) between the two stars.Our results show that eccentricity has a major role in the discrepancy between numerical and analytical waveforms until the very last few orbits, where "tidal" effects and missing high-order post-Newtonian coefficients also play a significant role.We test different methods for extrapolating the gravitational wave signal extracted at finite radii to null infinity. We show that an effective procedure for integrating the Newman-Penrose ψ 4 signal to obtain the gravitational wave strain h is to apply a simple high-pass digital filter to h after a time domain integration, where only the two physical motivated integration constants are introduced. That should be preferred to the more common procedures of introducing additional integration constants, integrating in the frequency domain or filtering ψ 4 before integration.PACS numbers: 04.25.D-, 04.40. Dg, 95.30.Lz, 97.60.Jd

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Convective Excitation of Inertial Modes in Binary Neutron Star Mergers

et al. 2018

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We present the first very long-term simulations (extending up to ∼140 ms after merger) of binary neutron star mergers with piecewise polytropic equations of state and in full general relativity. Our simulations reveal that, at a time of 30-50 ms after merger, parts of the star become convectively unstable, which triggers the excitation of inertial modes. The excited inertial modes are sustained up to several tens of milliseconds and are potentially observable by the planned third-generation gravitational-wave detectors at frequencies of a few kilohertz. Since inertial modes depend on the rotation rate of the star and they are triggered by a convective instability in the postmerger remnant, their detection in gravitational waves will provide a unique opportunity to probe the rotational and thermal state of the merger remnant. In addition, our findings have implications for the long-term evolution and stability of binary neutron star remnants.

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Modeling mergers of known galactic systems of binary neutron stars

Feo

Pietri

Maione

et al. 2016

Class. Quantum Grav.

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We present a study of the merger of six different known galactic systems of binary neutron stars (BNS) of unequal mass with a mass ratio between 0.75 and 0.99. Specifically, these systems are J1756-2251, J0737-3039A, J1906+0746, B1534+12, J0453+1559 and B1913+16. We follow the dynamics of the merger from the late stage of the inspiral process up to ∼20 ms after the system has merged, either to form a hyper-massive neutron star (NS) or a rotating black hole (BH), using a semirealistic equation of state (EOS), namely the seven-segment piece-wise polytropic SLy with a thermal component. For the most extreme of these systems (q = 0.75, J0453+1559), we also investigate the effects of different EOSs: APR4, H4, and MS1. Our numerical simulations are performed using only publicly available open source code such as, the Einstein Toolkit code deployed for the dynamical evolution and the LORENE code for the generation of the initial models. We show results on the gravitational wave signals, spectrogram and frequencies of the BNS after the merger and the BH properties in the two cases in which the system collapse within the simulated time. PACS numbers: 04.25.D-, 04.40.Dg, 95.30.Lz, 97.60.Jd arXiv:1608.02810v1 [gr-qc] 9 Aug 2016 J z (GM 2 /c)

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