Mass-radius relation for neutron stars in f(R) gravity
Sep 10, 2015
11 pages
Published in:
- Phys.Rev.D 93 (2016) 2, 023501
- Published: Jan 6, 2016
e-Print:
- 1509.04163 [gr-qc]
View in:
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Abstract: (APS)
We discuss the mass-radius diagram for static neutron star models obtained by the numerical solution of modified Tolman-Oppenheimer-Volkoff equations in f(R) gravity where the Lagrangians f(R)=R+αR2(1+γR) and f(R)=R1+ε are adopted. Unlike the case of the perturbative approach previously reported, the solutions are constrained by the presence of an extra degree of freedom, coming from the trace of the field equations. In particular, the stiffness of the equation of state determines an upper limit on the central density ρc above which the positivity condition of energy-matter tensor trace Tm=ρ-3p holds. In the case of quadratic f(R) gravity, we find higher masses and radii at lower central densities with an inversion of the behavior around a pivoting ρc which depends on the choice of the equation of state. When considering the cubic corrections, we find solutions converging to the required asymptotic behavior of the flat metric only for γ<0. A similar analysis is performed for f(R)=R1+ε considering ε as the leading parameter. We work strictly in the Jordan frame in order to consider matter minimally coupled with respect to geometry. This fact allows us to avoid ambiguities that could emerge in adopting the Einstein frame.Note:
- 10 pages, 6 figures, to appear in Phys. Rev. D
- 98.80.-k
- 04.50.Kd
- gravitation: f(R)
- neutron star: model
- space-time: static
- equation of state
- Tolman-Oppenheimer-Volkoff equation
- numerical calculations
- asymptotic behavior
- field equations
References(58)
Figures(15)
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