jetsimpy: A Highly Efficient Hydrodynamic Code for Gamma-ray Burst Afterglow
Title: jetsimpy: A Highly Efficient Hydrodynamic Code for Gamma-ray Burst Afterglow
Speaker: Dr. Hao Wang (Purdue University)
Time: 14:00pm, March 22, 2024
Location: 3-402, PMO Xianlin Campus
Abstract: Gamma-ray Burst afterglows are emissions from ultra-relativistic blastwaves produced by a narrow jet interacting with surrounding matter. Since the first multi-messenger observation of a neutron star merger, hydrodynamic modeling of GRB afterglows for structured jets with smoothly varying angular energy distributions has gained increased interest. While the evolution of a jet is well described by self-similar solutions in both ultra-relativistic and Newtonian limits, modeling the transitional phase remains challenging. This is due to the non-linear spreading of a narrow jet to a spherical configuration and the breakdown of self-similar solutions. Analytical models are limited in capturing these non-linear effects, while relativistic hydrodynamic simulations are computationally expensive which restricts the exploration of various initial conditions. In this work, we introduce a reduced hydrodynamic model that approximates the blastwave as an infinitely thin two-dimensional surface. Further assuming axial-symmetry, this model simplifies the simulation to one dimension and drastically reduces the computational costs. We have compared our modeling to relativistic hydrodynamic simulations, semi-analytic methods, and applied it to fit the light curve and flux centroid motion of GW170817. These comparisons demonstrate a high level of agreement and validate our approach. We have developed this method into a numerical tool, jetsimpy, which models the synchrotron GRB afterglow emission from a blastwave with arbitrary angular energy and Lorentz factor distribution. Although the code is built for GRB afterglow in mind, it is applicable to any relativistic jets. This tool is particularly useful in Markov Chain Monte Carlo studies and is provided to the community.