2017
DOI: 10.1142/s0218271817501279
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Critical mass, moment of inertia and universal relations of rapidly rotating neutron stars with exotic matter

Abstract: We calculate moment of inertia of neutron star with different exotic constituents such as hyperons and (anti)kaon condensates and study its variation with mass and spin frequency. The sets of equation of state, generated within the framework of relativistic mean field model with density-dependent couplings are adopted for the purpose. We follow the quasi-stationary evolution of rotating stars along the constant rest mass sequences, that varies considerably with different constituents in the equation of state. … Show more

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Cited by 16 publications
(11 citation statements)
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“…This holds good for other observable quantities also. When the ratio of critical mass i.e., the maximum mass at the mass-shedding limit and maximum mass for static neutron stars are plotted with normalised angular momentum with respect to maximum angular momentum, it also shows a universal relation [39,40]. However, this universality appears to be lost when we look at both HQ EoSs.…”
Section: Resultsmentioning
confidence: 90%
“…This holds good for other observable quantities also. When the ratio of critical mass i.e., the maximum mass at the mass-shedding limit and maximum mass for static neutron stars are plotted with normalised angular momentum with respect to maximum angular momentum, it also shows a universal relation [39,40]. However, this universality appears to be lost when we look at both HQ EoSs.…”
Section: Resultsmentioning
confidence: 90%
“…At the same time, certain relations among global parameters of compact stars were established (Haensel & Zdunik 1989;Friedman et al 1989;Shapiro et al 1989;Haensel et al 1995;Lasota et al 1996;Haensel et al 2009) and intensively studied in recent years which are highly insensitive to the input EoS and, therefore, are named universal (Yagi & Yunes 2017). The universal relations have been derived for a variety of systems under different conditions, for example, both for non-rotating (Yagi & Yunes 2013;Sotani et al 2013;Majumder et al 2015;Steiner et al 2016;Lenka et al 2017;Wei et al 2019;Kumar & Landry 2019;Raduta et al 2020;Suleiman et al 2021), slowly-rotating (Silva et al 2016) and rapidly rotating stars (Breu & Rezzolla 2016;Paschalidis et al 2018;Riahi et al 2019;Bozzola et al 2019;Khadkikar et al 2021;Koliogiannis & Moustakidis 2020), magnetized stars (Haskell et al 2014), finite temperature stars (Raduta et al 2020;Khadkikar et al 2021) in alternative theories of gravity (Doneva et al 2014;Pappas et al 2019;Popchev et al 2019;Yagi & Stepniczka 2021) ★ E-mail: noshad.khosravilargani@uwr.edu.pl † E-mail: tobias.fischer@uwr.edu.pl and in binaries (Manoharan et al 2021). For a review see Yagi & Yunes (2017).…”
Section: Introductionmentioning
confidence: 99%
“…Because we evaluate the stability of our neutron-star sequences in the absence of rotation, we are excluding supramassive (i.e. rotationstabilized) neutron stars, for which the universal relations deteriorate at high compactness[79].…”
mentioning
confidence: 99%