Unveiling f(R) Gravity with Void-Galaxy Cross-Correlation Multipoles

Abstract

Cosmic voids provide low-density environments where the scalar fifth force predicted by f(R) modified gravity can be weakly screened. We present a semi-analytical calculation of the monopole, dipole, and quadrupole of the void-galaxy cross-correlation function ξs(s,μ) in redshift space for the Hu-Sawicki f(R) model (n=1), combining scale-dependent growth induced by the scalaron with nonlinear spherical shell dynamics. The same framework can be generalized to metric f(R) theories for which G eff(k,a)/G is specified in the quasi-static limit. Our key results are: (1)~the monopole deviation from Λ CDM grows from +2.8\% for large voids (rv=30 h-1 Mpc) to +29.7\% for small voids (rv=11.7 h-1 Mpc) at |fR0|=10-5, a distinctive size-dependent signature of the Compton-scale scalaron response, with λC≈ 8 h-1 Mpc; (2)~nonlinear evolution amplifies the modified-gravity signal by A0≈ 4, bringing it within reach of ongoing and upcoming spectroscopic surveys such as DESI, Subaru PFS, Euclid, and Roman; (3) the gravitational potential contains a finite-range Yukawa component, producing a radially dependent dipole signature complementary to the density and velocity multipoles; (4) for the fiducial Hu-Sawicki evolution, the signal generally decreases toward higher redshift as the scalaron Compton wavelength becomes shorter, but remains potentially detectable at Stage-IV spectroscopic void samples. We show that the void-scale transition in the modified-gravity response, the joint sensitivity to density, velocity, and fifth-force contributions, and the nonlinear amplification around void shells make redshift-space void-galaxy multipoles a powerful semi-analytical probe of f(R) gravity and effective dark-energy inhomogeneities in modified gravity.