Superclusters from velocity divergence fields

Superclusters are a convenient way to partition and characterize the large-scale structure of the Universe. In this Letter, we explore the advantages of defining superclusters as watershed basins in the divergence velocity field. We apply this definition on diverse data sets generated from linear theory and N-body simulations, with different grid sizes, smoothing scales, and types of tracers. From this framework emerges a linear scaling relation between the average supercluster size and the autocorrelation length in the divergence field, a result that holds for one order of magnitude from 10 up to 100 Mpc h(-1). These results suggest that the divergence-based definition provides a robust context to quantitatively compare results across different observational or computational frameworks. Through its connection with linear theory, it can also facilitate the exploration of how supercluster properties depend on cosmological parameters, paving the way to use superclusters as cosmological probes.

Automated summary

This study explores the advantages of defining superclusters as watershed basins in the divergence velocity field, providing a robust context for quantitative comparison of results across different observational or computational frameworks. It reveals a linear scaling relation between the average supercluster size and the autocorrelation length in the divergence field, suggesting that supercluster properties depend on cosmological parameters.