TY - JOUR A1 - Rashti, Alireza A1 - Fabbri, Francesco Maria A1 - Brügmann, Bernd A1 - Chaurasia, Swami Vivekanandji A1 - Dietrich, Tim A1 - Ujevic, Maximiliano A1 - Tichy, Wolfgang T1 - New pseudospectral code for the construction of initial data JF - Physical review D N2 - Numerical studies of the dynamics of gravitational systems, e.g., black hole-neutron star systems, require physical and constraint-satisfying initial data. In this article, we present the newly developed pseudospectral code ELLIPTICA, an infrastructure for construction of initial data for various binary and single gravitational systems of all kinds. The elliptic equations under consideration are solved on a single spatial hypersurface of the spacetime manifold. Using coordinate maps, the hypersurface is covered by patches whose boundaries can adapt to the surface of the compact objects. To solve elliptic equations with arbitrary boundary condition, ELLIPTICA deploys a Schur complement domain decomposition method with a direct solver. In this version, we use cubed sphere coordinate maps and the fields are expanded using Chebyshev polynomials of the first kind. Here, we explain the building blocks of ELLIPTICA and the initial data construction algorithm for a black hole-neutron star binary system. We perform convergence tests and evolve the data to validate our results. Within our framework, the neutron star can reach spin values close to breakup with arbitrary direction, while the black hole can have arbitrary spin with dimensionless spin magnitude ∼0.8. Y1 - 2022 U6 - https://doi.org/10.1103/PhysRevD.105.104027 SN - 2470-0010 SN - 2470-0029 VL - 105 IS - 10 PB - American Physical Society CY - College Park ER - TY - JOUR A1 - Chaurasia, Swami Vivekanandji A1 - Dietrich, Tim A1 - Rosswog, Stephan T1 - Black hole-neutron star simulations with the BAM code BT - first tests and simulations JF - Physical review : D, Particles, fields, gravitation, and cosmology N2 - The first detections of black hole-neutron star mergers (GW200105 and GW200115) by the LIGO-Virgo-Kagra Collaboration mark a significant scientific breakthrough. The physical interpretation of pre- and postmerger signals requires careful cross-examination between observational and theoretical modelling results. Here we present the first set of black hole-neutron star simulations that were obtained with the numerical-relativity code BAM. Our initial data are constructed using the public LORENE spectral library, which employs an excision of the black hole interior. BAM, in contrast, uses the moving-puncture gauge for the evolution. Therefore, we need to "stuff" the black hole interior with smooth initial data to evolve the binary system in time. This procedure introduces constraint violations such that the constraint damping properties of the evolution system are essential to increase the accuracy of the simulation and in particular to reduce spurious center-of-mass drifts. Within BAM we evolve the Z4c equations and we compare our gravitational-wave results with those of the SXS collaboration and results obtained with the SACRA code. While we find generally good agreement with the reference solutions and phase differences less than or similar to 0.5 rad at the moment of merger, the absence of a clean convergence order in our simulations does not allow for a proper error quantification. We finally present a set of different initial conditions to explore how the merger of black hole neutron star systems depends on the involved masses, spins, and equations of state. Y1 - 2021 U6 - https://doi.org/10.1103/PhysRevD.104.084010 SN - 2470-0010 SN - 2470-0029 VL - 104 IS - 8 PB - American Physical Society CY - Ridge, NY ER -