Galaxy and halo angular clustering in ΛCDM and modified gravity cosmologies

Using a suite of N-body simulations, we study the angular clustering of galaxies, halos, and dark matter in A cold dark matter and modified gravity (MG) scenarios. We consider two general categories of such MG models, one is the foR) gravity, and the other is the normal branch of the Dvali-Gabadadze-Porrati brane world. To measure angular clustering we construct a set of observer-frame light cones and resulting mock sky catalogs. We focus on the area-averaged angular correlation functions WJ, and the associated 2 , and robustly measure them up to the ninth order using counts in cells. We find that 0.15 < z < 0.3 is the optimal redshift range to maximize the MG signal in our light cones. Analyzing various scales for the two types of statistics, we identify up to 20% relative departures in MG measurements from general relativity (GR), with varying signal significance. For the case of halos and galaxies, we find that third-order statistics offer the most sensitive probe of the different structure formation scenarios, with both W3 and the reduced skewness S3 reaching from 2 sigma to 4 sigma significance at angular scales theta 0.13 degrees. The MG clustering of the smooth dark matter field is characterized by even stronger deviations (greater than or similar to 5 sigma) from GR, albeit at a bit smaller scales of theta 0.08 degrees, where baryonic physics is already important. Finally, we stress that our mock halo and galaxy catalogs are characterized by rather low surface number densities when compared to existing and forthcoming state-of-the-art photometric surveys. This opens up exciting potential for testing GR and MG using angular clustering in future applications, with even higher precision and significance than reported here.

Automated summary

Using N-body simulations, the study examines the angular clustering of galaxies, halos, and dark matter in different gravity scenarios. Results show that the optimal redshift range for maximizing the modified gravity (MG) signal is between 0.15 < z < 0.3. Significant deviations from general relativity (GR) are observed in MG measurements, with different significance levels depending on the statistics used and the scale analyzed. The study suggests that third-order statistics provide sensitive probes for different structure formation scenarios. The findings also highlight the potential of future applications to test GR and MG with higher precision and significance.