An artist's impression of the Square Kilometre Array telescope in South Africa. (SKAO)When the Square Kilometre Array (SKA) Observatory goes online later this decade, it will create one of science’s biggest data challenges. The SKA Observatory is a global radio telescope project built in the Southern Hemisphere. There, views of our Milky Way are clearest and the SKA’s remote sites limit human-made radio interference.The project spans two sites: approximately 131,000 Christmas-tree-shaped antennas in western Australia and 200 large dish antennas in the Karoo region of South Africa. As part of this international collaboration, Canada has established a data-processing centre at the University of Victoria. Read more: Canada's participation in the world's largest radio telescope means new opportunities in research and innovation The SKA Observatory will produce around 600 petabytes of data each year. That amount would take 200 years to download using an at-home internet connection of 100 megabytes per second. This data volume exceeds by a significant margin even what is produced by the Large Hadron Collider, often considered to be the world’s premier big data science project.Research aimsAmong its many science goals, the SKA detects faint radio signals emitted during the Cosmic Dawn, roughly 50 million to one billion years after the Big Bang, when the very first stars and galaxies lit up the universe. The SKA will also test Albert Einstein’s theory of general relativity by timing signals from pulsars (rapidly spinning neutron stars) with high accuracy. Another goal is understanding fast radio bursts – brief, intense radio pulses from distant sources. The SKA is expected to detect fast radio bursts far more frequently than current instruments, providing a large dataset to help determine their cause, building on work done by facilities like Canada’s CHIME telescope. Initial data from the SKA is expected in 2027, with the start of major science operations in 2029 as the array is built and commissioned in phases. The first image from an early working version of the SKA Observatory’s SKA-Low telescope, which is currently under construction in western Australia. (SKAO), CC BY Canada’s roleHandling the large volume and complexity of SKA data requires a global network of specialized computing facilities, collectively known as SKA Regional Centres (SRCs). Canada became a member of the SKA Observatory research project in 2024. Shortly after joining, Canada committed to establishing one such centre. The Canadian SRC (CanSRC) will be the sole SRC in the Americas, serving as an important node for processing, storing and providing streamlined access to SKA data. It will allow researchers to focus on scientific analysis rather than data management hurdles.Big AstronomyThe SKA is part of astronomy’s ongoing evolution toward “Big Science,” where international collaboration becomes essential for scientific breakthroughs. This large-scale approach not only changes how science is funded, but also how it is conducted. While the SKA will still accommodate traditional investigator-led proposals — where individual scientists or small teams request specific telescope time and computational resources for more focused projects — most of its observing power will target ambitious, multi-year projects designed by large international teams.Canadian researchers participate in all of the SKA Science Working Groups and have co-chaired four of them in recent years. Canada is recognized as a world leader in studies of pulsars, cosmic magnetism and transients, as well as in low-frequency cosmology, areas where the SKA will make some of its most transformative discoveries. The centre of our Milky Way galaxy as seen by MeerKAT, a South African radio telescope that will become part of the SKA. (South African Radio Astronomy Observatory), CC BY Astronomical data managementBuilding, developing and managing CanSRC requires collaboration among the National Research Council’s Canadian Astronomy Data Centre, with four decades of experience in astronomical data management; the Digital Research Alliance of Canada, offering high-performance computing resources; CANARIE, operating the high-speed research network for data transfer; and the University of Victoria’s Arbutus cloud platform, supplying the scalable infrastructure. The project leverages expertise concentrated within the University of Victoria’s Astronomy Research Centre, which brings together researchers from the University of Victoria, the National Research Council Herzberg Astronomy and Astrophysics Research Centre and TRIUMF, Canada’s national particle accelerator centre.Importantly, CanSRC ensures that researchers have access to SKA data. The capabilities developed through CanSRC will strengthen Canada’s digital ecosystem for the future.Digital discoveryCanSRC will serve as a gateway for developing and expanding the use of advanced data methods and algorithms, helping scientists from research and industry sectors harness massive datasets.Applications of these techniques extend far beyond astronomy, with potential uses in medical imaging, remote sensing and artificial intelligence.Falk Herwig receives funding from the National Research Council of Canada and the Natural Science and Engineering Research Council of Canada. JJ Kavelaars receives funding from the National Research Council of Canada and the Natural Science and Engineering Research Council of Canada. Sébastien Fabbro receives funding from the National Research Council of Canada and the Natural Science and Engineering Research Council of Canada.Simon Blouin does not work for, consult, own shares in or receive funding from any company or organisation that would benefit from this article, and has disclosed no relevant affiliations beyond their academic appointment.