Eunyu LeeDepartment of Physics, College of Natural Sciences, UNIST, Korea, Dongsu RyuDepartment of Physics, College of Natural Sciences, UNIST, Korea, Hyesung KangDepartment of Earth Sciences, Pusan National University, Korea
{"title":"Morphology and Mach Number Distribution of Merger Shock Surfaces in Merging Galaxy Clusters","authors":"Eunyu LeeDepartment of Physics, College of Natural Sciences, UNIST, Korea, Dongsu RyuDepartment of Physics, College of Natural Sciences, UNIST, Korea, Hyesung KangDepartment of Earth Sciences, Pusan National University, Korea","doi":"arxiv-2409.09924","DOIUrl":null,"url":null,"abstract":"In a binary merger of two subclusters with comparable masses, a pair of\nmerger shocks are typically generated, often manifesting as double radio\nrelics. Using cosmological hydrodynamic simulations, we identify major merger\nevents with mass ratio $\\mathcal{M}_1/\\mathcal{M}_2\\lesssim4$ and impact\nparameter $b/r_{\\rm vir,1}\\lesssim1$, where $r_{\\rm vir,1}$ is the virial\nradius of the larger subcluster. We analyze merger shock surfaces approximately\n1 Gyr after the pericenter passage, focusing on their morphology and the\ndistribution of the Mach number, $M_s$, of their constituent shock zones. The\nshock surfaces exhibit an elongated shape with a minor-to-major axis ratio of\n$\\sim0.6-0.9$ and cover the area of $\\sim5-20\\%$ of the enclosed sphere. The\narea ratio of the two shock surfaces roughly scales with\n$\\mathcal{M}_1/\\mathcal{M}_2$, typically positioning the larger shock ahead of\nthe smaller subcluster. The axis connecting the two subclusters generally does\nnot pass through the centers of the shock surfaces, due to the nonzero impact\nparameter and the turbulent flows around them. The distribution of $M_s$ of\nshock zones on each surface can be approximated by a log-normal function,\npeaking at $M_{s,\\rm{peak}}\\approx2-4.5$ and extending up to $\\sim10$. The\nsurface-area-weighted and X-ray-emissivity-weighted average Mach numbers are\ncomparable, with ${\\langle{M_s}\\rangle}_{\\rm{area}}\\approx2.3-4.4$ and\n${\\langle{M_s}\\rangle}_{X}\\approx2-4$. In contrast, the\ncosmic-ray-energy-flux-weighted average Mach numbers are higher with\n${\\langle{M_s}\\rangle}_{\\rm{CR}}\\approx3-5$. This discrepancy aligns with the\ndifferences between Mach numbers derived from X-ray and radio observations of\nradio relic shocks. On the other hand, we find that mostly\n${\\langle{M_s}\\rangle}_{X}\\gtrsim2$ for simulated merger shocks, although\nshocks with $M_{\\rm X-ray}\\lesssim2$ are often reported in observations.","PeriodicalId":501343,"journal":{"name":"arXiv - PHYS - High Energy Astrophysical Phenomena","volume":"34 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2024-09-16","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"arXiv - PHYS - High Energy Astrophysical Phenomena","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/arxiv-2409.09924","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 0
Abstract
In a binary merger of two subclusters with comparable masses, a pair of
merger shocks are typically generated, often manifesting as double radio
relics. Using cosmological hydrodynamic simulations, we identify major merger
events with mass ratio $\mathcal{M}_1/\mathcal{M}_2\lesssim4$ and impact
parameter $b/r_{\rm vir,1}\lesssim1$, where $r_{\rm vir,1}$ is the virial
radius of the larger subcluster. We analyze merger shock surfaces approximately
1 Gyr after the pericenter passage, focusing on their morphology and the
distribution of the Mach number, $M_s$, of their constituent shock zones. The
shock surfaces exhibit an elongated shape with a minor-to-major axis ratio of
$\sim0.6-0.9$ and cover the area of $\sim5-20\%$ of the enclosed sphere. The
area ratio of the two shock surfaces roughly scales with
$\mathcal{M}_1/\mathcal{M}_2$, typically positioning the larger shock ahead of
the smaller subcluster. The axis connecting the two subclusters generally does
not pass through the centers of the shock surfaces, due to the nonzero impact
parameter and the turbulent flows around them. The distribution of $M_s$ of
shock zones on each surface can be approximated by a log-normal function,
peaking at $M_{s,\rm{peak}}\approx2-4.5$ and extending up to $\sim10$. The
surface-area-weighted and X-ray-emissivity-weighted average Mach numbers are
comparable, with ${\langle{M_s}\rangle}_{\rm{area}}\approx2.3-4.4$ and
${\langle{M_s}\rangle}_{X}\approx2-4$. In contrast, the
cosmic-ray-energy-flux-weighted average Mach numbers are higher with
${\langle{M_s}\rangle}_{\rm{CR}}\approx3-5$. This discrepancy aligns with the
differences between Mach numbers derived from X-ray and radio observations of
radio relic shocks. On the other hand, we find that mostly
${\langle{M_s}\rangle}_{X}\gtrsim2$ for simulated merger shocks, although
shocks with $M_{\rm X-ray}\lesssim2$ are often reported in observations.