Cosmic Web Dissection in Fuzzy Dark Matter Cosmologies
First author: Tibor Dome
On large cosmological scales, anisotropic gravitational collapse is manifest in the dark cosmic web. Its statistical properties are well known for the standard $\Lambda$CDM cosmology, yet become modified for alternative dark matter models such as fuzzy dark matter (FDM). In this work, we assess for the first time the relative importance of cosmic nodes, filaments, walls and voids in a cosmology with small-scale suppression of power such as FDM. By applying the NEXUS+ Multiscale Morphology Filter technique to cosmological $N$-body simulations of FDM-like cosmologies, we quantify the mass and volume filling fractions of cosmic environments at redshifts $z\sim 3.4-5.6$ and find that 2D cosmic sheets host a larger share of the matter content of the Universe ($\sim 5$% increase for the $m=7 \times 10^{-22}$ eV model compared to CDM) as the particle mass $m$ is reduced. We find that the suppression of node-, filament-, wall- and void-conditioned halo mass functions at the low-mass end can occur well above the half-mode mass $M_{1/2}$. We show that log overdensity PDFs are more peaked in FDM-like cosmologies with medians shifted to higher values, a result of the suppression of the low overdensity tail as $m$ is reduced. Skewness estimates $S_3$ of the unconditioned overdensity PDF $P(\delta)$ in FDM-like cosmologies are systematically higher than in CDM, more so at high redshift $z\sim 5.5$ where the $m=10^{-22}$ eV model differs from CDM by $\sim 2 \sigma$. Accordingly, we advocate for the usage of $P(\delta)$ as a testbed for constraining FDM and other alternative dark matter models.