We report a numerical discovery that the formations of cosmic voids are closely linked with the mechanism through which the giant galaxies on void surfaces establish elliptical shapes, redder colors, and lower sSFR. Identifying the voids from the TNG300-1 simulations via the Void-Finder algorithm, we explore if and how the shapes of the TNG galaxies located on void surfaces are aligned with the directions toward the void centers. Noting that only the giant void-surface galaxies with stellar masses M_ 10^10. 5\, h^-1\, M_ exhibit significant tendency of perpendicular alignments, we dichotomize them into two M_-controlled samples according to their morphologies (elliptical or spiral), colors (redder or bluer), sSFR (lower or higher) and stellar ages (older or younger). It is found that the void-galaxy perpendicular alignment becomes stronger for the cases that the void-surface galaxies have elliptical shapes, redder colors, and lower sSFR. The numerical results are also shown to be well described by the analytical one-parameter model derived under the assumption of the existence of a linear scaling between the covariance matrices of galaxy shape axes and local tidal tensors. Our result implies that the compression of adjacent matter due to the formation and rapid expansion of cosmic voids prevent them from radial infall/accretion, which in turn contribute to stalling and quenching the giant void-surface galaxies. Given that the formation epochs and expansion rates of cosmic voids depend sensitively on the dark energy equation of state, we also discuss a possibility of using the abundance of elliptical void-surface galaxies as a probe of dark energy.
Kang et al. (Sun,) studied this question.