Context. In previous papers it was shown that the function Γ(M,EOS)?≡?[αβ]GR/Λ0.8(R) is invariant (≈0.40) for pre main-sequence stars (PMS), white dwarfs (WD), and for neutron stars (NS) computed with equations of state using relativistic mean-field nucleon interactions. The form-factors αGR and βGR are related to the relativistic gravitational potential energy and the moment of inertia and are a key to handling the Jacobi virial equation, which is a powerful tool for investigating the stellar internal structure and evolution. We also found that Γ(M,EOS) is invariant for gaseous planets. Moreover, a macroscopic criterion of stability for NS was derived. Aims. To test if the invariance of Γ(M,EOS) also holds for an equation of state (EOS) in the non-relativistic framework, we compute NS models by adopting four different EOS prescriptions. We also computed models for hybrid and pure quark stars to extend the range of validity of the Γ(M,EOS) memory effect. To complete the three known final scenarios for stellar evolution, we follow the core-collapse supernova until the onset of formation of a black hole. Methods. Calculations from the PMS up to the WD stages were performed using the MESA code. Neutron, hybrid, and pure quark star models were computed using a modified version of the NSCool/TOV subroutines. The core-collapse supernova simulation was carried out using the code AGILE-IDSA. The relativistic moment of inertia and gravitational potential energy were computed through a fourth-order Runge-Kutta method. Results. We confirm that the function Γ(M,EOS) is invariant for PMS, WD, NS, hybrid, and pure quark stars and is independent of the mass and of the EOS (relativistic and non-relativistic frameworks). We show that our macroscopic criterion of stability is also valid for all mentioned compact stars. In a core-collapse supernova simulation, the PMS value of Γ(M,EOS) is recovered at the onset of formation of a black hole. Therefore, we conclude that, regardless of the final products of the stellar evolution, white dwarfs, neutron/hybrid/quark stars or proto-neutron star at the onset of formation of a black hole, they present a memory effect and recover the fossil value of Γ(M,EOS)?≈ 0.40, acquired during the PMS. Finally, we have shown the invariance of Γ(M,EOS) for earth-like planets as well.
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机译:上下文。在先前的论文中,证明了对于主序前恒星(PMS),白矮星(WD),函数Γ(M,EOS)?≡?[αβ] GR /Λ0.8(R)是不变的(≈0.40) ,对于使用相对论平均场核子相互作用以状态方程计算的中子星(NS)。形状因子αGR和βGR与相对论引力势能和惯性矩有关,是处理Jacobi病毒方程的关键,它是研究恒星内部结构和演化的有力工具。我们还发现,气态行星的Γ(M,EOS)是不变的。此外,得出了NS稳定的宏观标准。目的为了测试在非相对论框架中Γ(M,EOS)的不变性是否也适用于状态方程(EOS),我们通过采用四种不同的EOS处方来计算NS模型。我们还为混合和纯夸克星计算了模型,以扩展Γ(M,EOS)记忆效应的有效范围。为了完成三个已知的恒星演化最终场景,我们遵循核心坍缩的超新星,直到黑洞形成开始。方法。使用MESA代码执行从PMS到WD阶段的计算。使用NSCool / TOV子例程的修改版来计算中子,混合和纯夸克星模型。使用代码AGILE-IDSA进行了核塌陷超新星模拟。相对论惯性矩和重力势能通过四阶Runge-Kutta方法计算。结果。我们确认函数Γ(M,EOS)对于PMS,WD,NS,混合星和纯夸克星是不变的,并且与质量和EOS(相对论和非相对论框架)无关。我们证明了我们的宏观稳定标准对于所有提到的紧凑恒星也是有效的。在核塌陷超新星模拟中,Γ(M,EOS)的PMS值在黑洞形成开始时恢复。因此,我们得出结论,无论恒星演化的最终产物,白矮星,中子/杂种/夸克星还是原黑中子星在形成黑洞时便具有记忆效应并恢复了化石的价值。在PMS期间获取的Γ(M,EOS)的≈≈0.40。最后,我们还证明了类地行星的Γ(M,EOS)不变性。
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