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Cosmic Web Classification through Stochastic Topological Ranking (2404.01124v2)

Published 1 Apr 2024 in astro-ph.CO

Abstract: This paper introduces ASTRA (Algorithm for Stochastic Topological RAnking), a new method for classifying galaxies into cosmic web structures -voids, sheets, filaments, and knots -- specifically designed for large spectroscopic surveys. ASTRA operates on observed galaxy positions and a corresponding random catalog, generating probabilistic cosmic web classifications for both datasets. The method's key innovation lies in using random points to trace underdense regions, enabling robust identification of cosmic voids that are poorly sampled by galaxies. We evaluate ASTRA using N-body simulations (dark matter-only and hydrodynamical) and SDSS observational data, performing both visual inspections and quantitative analyses of mass and volume distributions. The algorithm successfully produces void catalogs with size functions following theoretical expectations and demonstrates consistent environmental statistics across diverse datasets. Comparative analysis against established cosmic web classifiers confirms ASTRA's effectiveness, particularly for filament identification. By incorporating both observed and random points in its classification scheme, ASTRA provides a full cosmic web characterization without requiring density field interpolation or fixed geometric assumptions. The method's ability to quantify spatial correlations among different cosmic web components offers promising avenues for enhancing cosmological parameter constraints through non-standard clustering statistics.

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References (37)
  1. THE SEVENTH DATA RELEASE OF THE SLOAN DIGITAL SKY SURVEY, The Astrophysical Journal Supplement Series, 182(2), 543–558.
  2. Galaxy And Mass Assembly (GAMA): the large-scale structure of galaxies and comparison to mock universes, MNRAS, 438(1), 177–194.
  3. The multiscale morphology filter: identifying and extracting spatial patterns in the galaxy distribution, A&A, 474(1), 315–338.
  4. The Spine of the Cosmic Web, ApJ, 723(1), 364–382.
  5. Minimal spanning trees, filaments and galaxy clustering, MNRAS, 216, 17–35.
  6. New York University Value-Added Galaxy Catalog: A Galaxy Catalog Based on New Public Surveys, AJ, 129(6), 2562–2578.
  7. How filaments of galaxies are woven into the cosmic web, Nature, 380(6575), 603–606.
  8. NEXUS: tracing the cosmic web connection, Monthly Notices of the Royal Astronomical Society, 429(2), 1286–1308.
  9. Cosmological Constraints from the BOSS DR12 Void Size Function, ApJ, 953(1), 46.
  10. A survey of galaxy redshifts. V. The two-point position and velocity correlations., ApJ, 267, 465–482.
  11. The evolution of large-scale structure in a universe dominated by cold dark matter, ApJ, 292, 371–394.
  12. ORIGAMI: DELINEATING HALOS USING PHASE-SPACE FOLDS, The Astrophysical Journal, 754(2), 126.
  13. β𝛽\betaitalic_β-Skeleton analysis of the cosmic web, MNRAS, 485(4), 5276–5284.
  14. Power-Spectrum Analysis of Three-dimensional Redshift Surveys, ApJ, 426, 23.
  15. A dynamical classification of the cosmic web, MNRAS, 396(3), 1815–1824.
  16. Automated detection of filaments in the large-scale structure of the Universe, Monthly Notices of the Royal Astronomical Society, 407(3), 1449–1463.
  17. A kinematic classification of the cosmic web, Monthly Notices of the Royal Astronomical Society, 425(3), 2049–2057.
  18. Linearization with cosmological perturbation theory, Monthly Notices of the Royal Astronomical Society, 425(4), 2443–2454.
  19. Bias and Variance of Angular Correlation Functions, ApJ, 412, 64.
  20. Tracing the cosmic web, Monthly Notices of the Royal Astronomical Society, 473(1), 1195–1217.
  21. Beyond BAO: Improving cosmological constraints from BOSS data with measurement of the void-galaxy cross-correlation, Phys. Rev. D, 100(2), 023504.
  22. The IllustrisTNG simulations: public data release, Computational Astrophysics and Cosmology, 6(1), 2.
  23. Constraining ν𝜈\nuitalic_νΛΛ\Lambdaroman_ΛCDM with density-split clustering, MNRAS, 522(1), 606–625.
  24. Cosmic voids in Sloan Digital Sky Survey Data Release 7, Monthly Notices of the Royal Astronomical Society, 421(2), 926–934.
  25. Multi-stream portrait of the cosmic web, Monthly Notices of the Royal Astronomical Society, 452(2), 1643–1653.
  26. Shapes and sizes of voids in the Lambda cold dark matter universe: excursion set approach, MNRAS, 367(4), 1629–1640.
  27. A hierarchy of voids: much ado about nothing, MNRAS, 350(2), 517–538.
  28. The persistent cosmic web and its filamentary structure – I. Theory and implementation, Monthly Notices of the Royal Astronomical Society, 414(1), 350–383.
  29. The cosmological simulation code gadget-2, Monthly Notices of the Royal Astronomical Society, 364(4), 1105–1134.
  30. Simulations of the formation, evolution and clustering of galaxies and quasars, Nature, 435(7042), 629–636.
  31. The Four Cosmic Tidal Web Elements from the β𝛽\betaitalic_β-skeleton, ApJ, 922(2), 204.
  32. VIDE: The Void IDentification and Examination toolkit, Astronomy and Computing, 9, 1–9.
  33. Detecting filamentary pattern in the cosmic web: a catalogue of filaments for the SDSS, MNRAS, 438(4), 3465–3482.
  34. Galaxy pairs align with galactic filaments, A&A, 576, L5.
  35. The void size function in dynamical dark energy cosmologies, J. Cosmology Astropart. Phys, 2019(12), 040.
  36. Improving SDSS Cosmological Constraints through β𝛽\betaitalic_β-Skeleton Weighted Correlation Functions, arXiv e-prints, p. arXiv:2403.14165.
  37. Gravitational instability: An approximate theory for large density perturbations., A&A, 5, 84–89.

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