| Hyperion proto-supercluster | |
| Image Scale: | 2 |
| Epoch: | J2000 |
| Constellation: | Sextans |
| Major Axis Mpc: | 150Mpc |
| Minor Axis Mpc: | 60Mpc |
| Redshift: | 2.45 |
The Hyperion proto-supercluster is the largest and earliest known proto-supercluster, 5,000 times the mass of the Milky Way and seen at 20% of the current age of the universe. It was discovered in 2018 by analysing the redshifts of 10,000 objects observed with the Very Large Telescope in Chile.
The discovery was announced in late 2018.
The discovery team led by Olga Cucciati used computational astrophysics methods and astroinformatics; statistical techniques were applied to large datasets of galaxy redshifts, using a two-dimensional Voronoi tessellation to correlate gravitational interaction (virialization) of visible structures. The existence of non-visible (dark matter) structures was inferred.
Correlation was based on redshift data captured in a sky survey called VIMOS-VLT Deep Survey, using the Visible Multi Object Spectrograph (VIMOS) instrument of the Very Large Telescope in Chile, and other surveys to a lesser extent. Spectroscopic redshift data for 3,822 objects (galaxies) was selected.
The discovery was published in Astronomy & Astrophysics in September 2018.
The structure is estimated to weigh 4.8 × 1015 solar masses (about 5,000 times the mass of the Milky Way) and to extend NaNMpc. It lies within the two square degree Cosmic Evolution Survey (COSMOS) field of the constellation Sextans.[1] Hyperion's redshift is z=2.45 putting it 11 billion light years from Earth; it existed at less than 20% of the present age of the Universe. Eventually it is "expected to evolve into something similar to the immense structures in the local universe such as the superclusters making up the Sloan Great Wall or the Virgo Supercluster".
The supercluster contains dark matter, evidenced by a mismatch between the visible objects in it and their computed gravitational binding. As a relic from the early Universe, the dark matter data could be used to test cosmological theories. As the 2018 paper authors note, "the identification of massive/complex proto-clusters at high redshift could be useful to give constraints on dark matter simulations" of the Lambda-CDM model.