Since the beginning of this project, we have carried out some of the largest cosmological simulations in the world to study the large-scale distribution of matter, gas, and galaxies in the Universe. These calculations were able to resolve the smallest clumps of dark matter where we expect large galaxies to form, and over regions of billions of light-years across.
Even though a single simulation originally takes weeks of processing in a large supercomputer, we have designed a method that uses one simulation to create another one with different assumptions about the Universe. This transformation takes only 5 minutes in a normal desktop, so we have been able to create thousands of new pseudo-simulations as a function of the amount of dark matter, neutrinos, and the properties of dark energy.
Complementing these results, we developed physical models that predict the distribution of gas and stars inside our simulations, and how they are related to dark matter. These models include the impact of the formation of stars and the energy released by supermassive black holes, among other effects. In parallel, we developed new techniques to predict the spatial distribution of galaxies and their shapes. All these models have been extensively tested against hydro-dynamical simulations and other galaxy formation models.
Employing these data, we have trained machine learning algorithms so that the predictions could be obtained in a fraction of a second. We made these results publicly available so that they can benefit researchers from all over the world. These tools have also been adopted by some of the most advanced cosmological surveys to date, such as ESA's Euclid mission.
These novel methods have enabled the interpret cosmological data over a range of scales never used before, and to employ them for inferring the parameters that determine the evolution and properties of our Universe. Specifically, we analysed the latest data release from the Dark Energy Survey, modelling its gravitational lensing measurements to infer the amplitude of fluctuations as well as the amount of gas in massive galaxy clusters.
All these results have been described in detail in more than 50 peer-reviewed scientific publications, as well as in multiple scientific conferences and events designed for the general public.