Tracing Cosmological Signature with Doppler Lensing: Insights from Cosmological Simulations

Abstract

Doppler lensing, a relativistic effect resulting from the peculiar velocities of galaxies along the line of sight, provides insight into the large-scale structure of the Universe. Relativistic simulations are essential for modeling Doppler lensing because they incorporate gravity and motion in spacetime. We compare two relativistic N-body simulation frameworks, GEVOLUTION and SCREENING, to calculate Doppler lensing convergence in cosmic voids of different sizes and halos of different masses. Our analysis reveals scale-dependent performance: SCREENING shows larger differences in small voids (radius range: 15--25 Mpc/h) with a mean absolute relative difference of 38.5\%, due to linearized dynamics failing in nonlinear regimes. Medium voids (25--35 Mpc/h) show better agreement (9.5\% mean difference). For large voids (35--45 Mpc/h), SCREENING exhibits intermediate differences (16.9\% mean difference) with central instabilities. Moreover, our Doppler convergence analysis with massive halos (1011.5--1014 ~h-1M) demonstrates excellent consistency (1.6--3.6\% mean difference). These findings provide clear guidance for simulation choice: GEVOLUTION is recommended for precision studies critical to or modified gravity tests, while SCREENING offers a computationally efficient alternative for relativistic treatments with large catalogs of voids and halos, assisting future astrophysical surveys.