{"title":"具有指数单位的旋转多面体的精确解及其近似和一些应用","authors":"M. Vavrukh, D. Dzikovskyi","doi":"10.31577/caosp.2020.50.4.748","DOIUrl":null,"url":null,"abstract":". The fundamental stages of development of the polytropic theory of stars with axial rotation are considered as a generalization of the Lane-Emden theory. The solution of the differential equilibrium equation for the polytropic star model with index n = 1 and axial rotation with the angular velocity ω is presented in the form of infinite series of the Legendre polynomials and the spherical Bessel functions. Two variants of the approximate solution in the form of the finite number of terms are proposed. Integration constants were found in a self-consistent way using the integral form of the equilibrium equation and the iteration numerical method. Dependence of the geometrical and physical characteristics of the model on the dimensionless angular velocity Ω = ω (2 πGρ c ) − 1 / 2 (where ρ c is the density in the centre) is analyzed. A comparison with the results of other authors is performed. The obtained critical value of the angular velocity Ω max , when an instability occurs is smaller than in other works (Chandrasekhar, 1933; James, 1964, and et al.). The inverse problem is also considered – a determination of the polytropic model parameters for individual stars based on the solution of the equilibrium equation according to the values of their masses and radii, which are known from observations. In particular, the model parameters for the star α Eri, as well as a similar “class” of the star models of types O5 ÷ G0, were determined. The solution of the equilibrium equation for the polytrope n = 1+ δ (where δ is a small value) is obtained using the method of perturbation theory.","PeriodicalId":50617,"journal":{"name":"Contributions of the Astronomical Observatory Skalnate Pleso","volume":" ","pages":""},"PeriodicalIF":0.4000,"publicationDate":"2020-11-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"6","resultStr":"{\"title\":\"Exact solution for the rotating polytropes with index unity, its approximations and some applications\",\"authors\":\"M. Vavrukh, D. Dzikovskyi\",\"doi\":\"10.31577/caosp.2020.50.4.748\",\"DOIUrl\":null,\"url\":null,\"abstract\":\". The fundamental stages of development of the polytropic theory of stars with axial rotation are considered as a generalization of the Lane-Emden theory. The solution of the differential equilibrium equation for the polytropic star model with index n = 1 and axial rotation with the angular velocity ω is presented in the form of infinite series of the Legendre polynomials and the spherical Bessel functions. Two variants of the approximate solution in the form of the finite number of terms are proposed. Integration constants were found in a self-consistent way using the integral form of the equilibrium equation and the iteration numerical method. Dependence of the geometrical and physical characteristics of the model on the dimensionless angular velocity Ω = ω (2 πGρ c ) − 1 / 2 (where ρ c is the density in the centre) is analyzed. A comparison with the results of other authors is performed. The obtained critical value of the angular velocity Ω max , when an instability occurs is smaller than in other works (Chandrasekhar, 1933; James, 1964, and et al.). The inverse problem is also considered – a determination of the polytropic model parameters for individual stars based on the solution of the equilibrium equation according to the values of their masses and radii, which are known from observations. In particular, the model parameters for the star α Eri, as well as a similar “class” of the star models of types O5 ÷ G0, were determined. 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引用次数: 6
摘要
.具有轴向旋转的恒星的多变理论发展的基本阶段被认为是Lane-Emden理论的推广。指数为n=1、轴旋转角速度为ω的多变恒星模型的微分平衡方程的解以勒让德多项式和球面贝塞尔函数的有限级数的形式给出。提出了有限项形式的近似解的两种变体。利用平衡方程的积分形式和迭代数值方法,以自洽的方式求出了积分常数。模型的几何和物理特性对无量纲角速度的依赖性Ω = ω(2πGρc)−1/2(其中ρc是中心的密度)进行了分析。与其他作者的结果进行了比较。获得的角速度临界值Ω 当不稳定发生时,max比其他工作中的要小(Chandrasekhar,1933;James,1964,and et al.)。还考虑了反问题——根据观测中已知的恒星质量和半径的值,根据平衡方程的解,确定单个恒星的多变模型参数。特别是,确定了αEri恒星的模型参数,以及O5÷G0类型的类似“类别”恒星模型。用微扰理论的方法得到了n=1+δ(其中δ是一个小值)多索的平衡方程的解。
Exact solution for the rotating polytropes with index unity, its approximations and some applications
. The fundamental stages of development of the polytropic theory of stars with axial rotation are considered as a generalization of the Lane-Emden theory. The solution of the differential equilibrium equation for the polytropic star model with index n = 1 and axial rotation with the angular velocity ω is presented in the form of infinite series of the Legendre polynomials and the spherical Bessel functions. Two variants of the approximate solution in the form of the finite number of terms are proposed. Integration constants were found in a self-consistent way using the integral form of the equilibrium equation and the iteration numerical method. Dependence of the geometrical and physical characteristics of the model on the dimensionless angular velocity Ω = ω (2 πGρ c ) − 1 / 2 (where ρ c is the density in the centre) is analyzed. A comparison with the results of other authors is performed. The obtained critical value of the angular velocity Ω max , when an instability occurs is smaller than in other works (Chandrasekhar, 1933; James, 1964, and et al.). The inverse problem is also considered – a determination of the polytropic model parameters for individual stars based on the solution of the equilibrium equation according to the values of their masses and radii, which are known from observations. In particular, the model parameters for the star α Eri, as well as a similar “class” of the star models of types O5 ÷ G0, were determined. The solution of the equilibrium equation for the polytrope n = 1+ δ (where δ is a small value) is obtained using the method of perturbation theory.
期刊介绍:
Contributions of the Astronomical Observatory Skalnate Pleso" (CAOSP) is published by the Astronomical Institute of the Slovak Academy of Sciences (SAS). The journal publishes new results of astronomical and astrophysical research, preferentially covering the fields of Interplanetary Matter, Stellar Astrophysics and Solar Physics. We publish regular papers, expert comments and review contributions.