📝 SummarXiv

Abstract

Protohalos, primordial regions in the initial cosmic density field that evolve into dark matter halos, are crucial for understanding cosmic structure formation. Motivated by the potential to reconstruct protohalo positions and shapes from observed galaxies using a novel approach grounded in optimal transport theory, we revisit the relationship between the structural properties of protohalos and the formation histories, concentrations, and final morphologies of their associated dark matter halos. To better understand halo assembly, we introduce a new estimator defined by an integral over redshifts and compare its performance to $z_{50}$, the commonly used redshift at which half of the final halo mass is formed. We quantify protohalo structure using the three invariants of the inertia, deformation, and energy shear tensors. Although past research has correlated the first two invariants of the deformation and energy tensors with halo formation, our findings reveal that the third invariant also significantly correlates with the final halo shape. We discuss the prospect of using optimal transport to connect our protohalo results to observations of high-redshift protoclusters to better align theoretical models with observational data.