White Dwarf Structure in f(Q) Gravity

Abstract

In this work, we investigate the equilibrium structure of white dwarfs within the covariant formulation of symmetric teleparallel f(Q) gravity, in which gravity is described by the nonmetricity scalar Q instead of spacetime curvature. We consider static and spherically symmetric stellar configurations composed of cold, fully degenerate electron matter and adopt a quadratic form of the gravitational Lagrangian, f(Q)=Q+α Q2, where α quantifies deviations from general relativity. The corresponding modified stellar structure equations are solved numerically in conjunction with the Chandrasekhar equation of state. We examine the impact of the parameter α on the internal structure and global properties of white dwarfs, including the radial profiles of the metric potentials, pressure, density, nonmetricity scalar, and enclosed mass, as well as the mass--radius relation. While negative values of α were explored, they lead to unstable or nonphysical configurations at high densities; therefore, the analysis is restricted to non-negative values of α. Our results show that nonmetricity corrections produce significant deviations from the general relativistic predictions in the high-density regime. In particular, increasing α modifies the equilibrium configurations and leads to a reduction in the maximum mass relative to the Chandrasekhar limit, accompanied by corresponding changes in the stellar radius and interior profiles. For α = 5×1018\,cm2, we obtain a maximum mass M=1.3519\,M and radius R=2228.85\,km, which are consistent with the observational constraints of the ultra-massive white dwarf ZTF J1901+1458. These findings suggest that white dwarfs can provide a complementary astrophysical probe for testing the viability of f(Q) gravity in the strong-field regime.

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