Naturaleza y Tecnología

Con el fin de discutir la cuestión de cuáles serán los mayores objetos que resistirán a la implacable dispersión por cuenta de la expansión acelerada del Universo, explicaré como se forman y evolucionan los sistemas y las estructuras astrofísicas a escalas muy grandes, como las vemos en el presente y como se estima cuales podrán sobrevivir en el futuro.

Abell, G.O. (1961). Evidence regarding second-order clustering of galaxies and interactions between clusters of galaxies. AJ, 66, 607–613.

Adami, C.; Giles, P.; Koulouridis, E.; Pacaud, F.; Caretta, C.A.; Pierre, M. et al. (2018). The XXL Survey. XX. The 365 cluster catalogue. A&A, 620, A5 (28pp.). https://doi.org/10.1051/0004-6361/201731606

Araya-Melo, P.A.; Reisenegger, A.; Meza, A.; van de Weygaert, R.; Dünner, R.; Quintana, H. (2009). Future evolution of bound superclusters in an accelerating Universe. MNRAS, 399 (1), 97–120.

Bardelli, S.; Zucca, E.; Vettolani, G.; Zamorani, G.; Scaramella, R.; Collins, C.A.; MacGillivray, H.T. (1994). A study of the core of the Shapley concentration - I. The sample. MNRAS, 267, 665–691.

Caretta, C.A.; Maia, M.A.G.; Kawasaki, W.; Willmer, C.N.A. (2002). The Aquarius Superclusters. I. Identification of Clusters and Superclusters. AJ, 123 (3), 1200–1215. https://doi.org/10.1086/338894

Caretta, C.A.; Andernach, H.; Chow-Martínez, M.; Coziol, R.; De Anda-Suárez, J.; Hernández-Aguayo, C.; Islas-Islas, J.M.; Mireles-Vidales, M.M.; Muñiz-Torres, M.A.; Santoyo-Ruiz, H.; Trejo-Alonso, J.J.; Venkatapathy, Y.; Zúñiga, J.M. (2023). Tracing the Assembly Histories of Galaxy Clusters in the Nearby Universe. RMxAA, 59, 345–377. https://doi.org/10.22201/ia.01851101p.2023.59.02.13

Chiueh, T.; He, X.-G. (2002). Future island universes in a background universe accelerated by a cosmological constant and by quintessence. Physical Review D, 65 (12), 123518.

Chon, G.; Böhringer, H.; Zaroubi, S. (2015). On the definition of superclusters. A&A, 575, L14 (5pp.)

.

Chow-Martínez, M.; Andernach, H.; Caretta, C.A.; Trejo-Alonso, J.J. (2014). Two new catalogues of superclusters of Abell/ACO galaxy clusters out to redshift 0.15. MNRAS, 445 (4), 4073–4085. https://doi.org/10.1093/mnras/stu1961

Davis, M.; Efstathiou G.; Frenk, C.S.; White, S.D.M. (1985). The Evolution of LSS in a Universe dominated by Cold Dark Matter. ApJ, 292, 371–395. https://doi.org/10.1086/163168

Dünner, R.; Araya, P.A.; Meza, A.; Reisenegger, A. (2006). The limits of bound structures in the accelerating Universe. MNRAS, 366 (3), 803–811.

Dupuy, A.; Courtois, H.M.; Dupont, F. et al. (2019). Partitioning the Universe into gravitational basins using the cosmic velocity field. MNRAS, 489(1), L1–L6. https://doi.org/10.1093/mnrasl/slz115

Einasto, M.; Einasto, J.; Tago, E.; Müller, V.; Andernach, H. (2001). Optical and X-Ray Clusters as Tracers of the Supercluster-Void Network. I. Superclusters of Abell and X-Ray Clusters. AJ, 122(5), 2222–2242. https://doi.org/10.1086/323707

Einasto, M.; Deshev, B.; Tenjes, P. et al. (2020). Multiscale cosmic web detachments, connectivity, and preprocessing in the supercluster SCl A2142 cocoon. A&A, 641, A172 (19pp.). https://doi.org/10.1051/0004-6361/202037982

Fixsen, D.J. (2009). The Temperature of the Cosmic Microwave Background. ApJ, 707 (2), 916–920. https://doi.org/10.1088/0004-637X/707/2/916. S2CID 119217397

Gramann, M.; Suhhonenko, I. (2002). Dynamical state of superclusters of galaxies: do superclusters expand, or have they started to collapse? MNRAS, 337 (4), 1417–1425.

Heinämäki, P.; Teerikorpi, P.; Douspis, M.; Nurmi, P.; Einasto, M.; Gramann, M.; Nevalainen, J.; Saar, E. (2022). Quasi-spherical superclusters. A&A, 668, A37 (14pp.). https://doi.org/10.1051/0004-6361/202244239

Kuhlen, M.; Vogelsberger, M.; Angulo, R. (2012). Numerical simulations of the dark universe: State of the art and the next decade. Phys. Dark Universe, 1, 50–93. https://doi.org/10.1016/j.dark.2012.10.002

Luparello, H.; Lares, M.; Lambas, D.G.; Padilla, N. (2011). Future virialized structures: an analysis of superstructures in the SDSS-DR7. MNRAS, 415 (1), 964–976.

Nagamine, K.; Loeb, A. (2003). Future evolution of nearby large-scale structures in a universe dominated by a cosmological constant. New Astronomy, 8 (5), 439–448.

Padmanabhan, T. (1993). Structure formation in the Universe, Cambridge University Press.

Partridge, R.B. (2019). The cosmic microwave background: from discovery to precision cosmology. En: H. Kragh y M.S. Longair (Eds.). The Oxford Handbook of the History of Modern Cosmology (pp. 292—345). Oxford University Press.

Santiago-Bautista, I.; Caretta, C.A.; Bravo-Alfaro, H.; Pointecouteau, E.; Andernach, H. (2020). Identification of filamentary structures in the environment of superclusters of galaxies in the Local Universe. A&A, 637, A31 (26 pp.). https://doi.org/10.1051/0004-6361/201936397

Small, T.A.; Sargent, W.L.W.; Hamilton, D. (1997). The Norris Survey of the Corona Borealis Supercluster. I. Observations and Catalog Construction. ApJS, 111 (1), 1–71.

Tanabashi M.; Hagiwara, K.; Hikasa, K. et al. (2018). Review of Particle Physics. Phys. Rev. D, 98, 030001. https://doi.org/10.1103/PhysRevD.98.030001

Tully, R.B. (1982). The Local Supercluster. ApJ 257, 389–422.

Tully, R.B.; Courtois, H.; Hoffman, Y.; Pomarède, D. (2014). The Laniakea supercluster of galaxies. Nature, 513 (7516), 71–73.

Zel’dovich, Ya. B. (1970). Gravitational instability: An approximate theory for large density perturbations. A&A, 5, 84–89.

Zúñiga, J.M.; Caretta, C.A.; González, A.P.; García-Manzanárez, E. (2024a). Testing an Entropy Estimator Related to the Dynamical State of Galaxy Clusters. RMxAA, 60, 141–164. https://doi.org/10.22201/ia.01851101p.2024.60.01.11

Zúñiga, J.M.; Caretta, C.A.; Andernach, H. (2024b). Nucleation regions in the Large-Scale Structure I: A catalogue of cores in nearby rich superclusters. PASA, 41, e078 (27 pp.). https://doi.org/10.1017/pasa.2024.49