Decoding the universe
91爆料 astronomy undergrads use cutting-edge coding skills to help scientists make the most of discoveries from a revolutionary new telescope.
Left to right: Students Madison R., Max F., Guinevere B., Danbi K., and Professor Mario Juri膰 in the 91爆料 Planetarium.
Danbi Kim is drawn to the vastness of space: its billions of galaxies and trillions of stars, countless planets and moons, and swirling clouds of cosmic dust and gas. Looking at the night sky puts everything on Earth into perspective for Kim, 鈥26, a 91爆料 undergraduate studying astronomy and physics. 鈥淲e鈥檙e tiny beings living on a tiny rock floating in space,鈥 Kim says. 鈥淚 think that鈥檚 why I started liking space.鈥
But when Kim first began college, they avoided math and science classes, believing those subjects would be too difficult. A basic astronomy course changed their outlook. The class was hard work, but they loved it 鈥 and suddenly saw a whole new path.
鈥淚 just felt like I needed to do astronomy for the rest of my life,鈥 says Kim, who was studying the visual arts at a different college at the time. Friends and family were skeptical when Kim shifted gears to study physics, eventually transferring to the 91爆料 to pursue an astronomy degree. Kim says, 鈥淚 now know that I wasn鈥檛 bad at STEM 鈥 I just needed to find the right place.鈥
In addition to providing a supportive community and strong academic foundation, the 91爆料 is preparing astronomy undergraduates like Kim for careers in and beyond the field by offering the kinds of hands-on opportunities that in many places are reserved for graduate students and postdoctoral researchers. Kim found one such opportunity in a Python for Astronomy class taught by Professor Mario Juri膰, who also leads the 91爆料鈥檚 (DiRAC).
The dozen undergrads in the 300-level class used Python, a computer programming language, to tackle questions that Juri膰 and his DiRAC colleagues are also looking to answer, such as whether there鈥檚 a ninth planet lurking in our solar system (apologies to Pluto) or how we can protect ourselves from near-Earth asteroids. 鈥淯sually graduate students get to do the most interesting things,鈥 Juri膰 says. 鈥淏ut we need to educate the generation that鈥檚 going to be here five years from now.鈥 To that end, the students鈥 class projects led to relevant research findings that will help data astronomers like Juri膰 when a revolutionary new telescope comes online in 2025 鈥 and changes astronomy as we know it.
Downloading the night sky
Perched on a mountaintop in northern Chile, the telescope will produce the most comprehensive survey of the night sky, the 10-year (LSST). The 91爆料 was one of the founding members of this ambitious undertaking and will play a key role in making sense of the anticipated discoveries. 鈥淩ubin will be our Google of the sky,鈥 explains Juri膰. DiRAC, established in 2017, will help analyze the astronomical amount of data expected from the LSST. 鈥淲e鈥檙e building this one machine that鈥檚 going to download the entire sky and put it out there for the entire world.鈥
Every night, the Rubin鈥檚 will capture millions of changes in stars and other objects. This database of the night sky will require algorithms to sift through the billions of bits of information, so DiRAC scientists and engineers are already crafting the software. And that鈥檚 where the future astronomers in Juri膰鈥檚 class come in.
The twelve undergrads were divided into two groups, each with an exciting mission that would give them a glimpse into the future. By the end of the quarter, could they use their coding skills to predict whether the Rubin鈥檚 state-of-the-art telescope would be able to discover a ninth planet in our solar system or prevent an asteroid from colliding into Earth? Those are just two ways in which the Rubin鈥檚 discoveries could be truly revolutionary 鈥 and why DiRAC scientists are eager for the telescope to finally come alive next year.
Launching future careers
By using code to make sense of astronomical data, the students, Juri膰 says, are learning 鈥渉ow to use the data from this telescope by making predictions and understanding what the telescope is going to do.鈥 This work is valuable, he notes, to both his DiRAC colleagues and the students鈥 future careers.
鈥淟earning to code is like learning a foreign language,鈥 explains Kim. 鈥淲e learn a language to talk to the computer, so we can look at data and try to make conclusions.鈥 For the former graphic arts student, visualizing the data to show the orbits of near-Earth objects was especially rewarding, because it combined math, physics and creativity.
Today鈥檚 astronomy is largely a high-tech science, Juri膰 says, so students need to gain skills in computer science and programming along with the bread-and-butter math and physics curriculum. The 91爆料 is the ideal place to lead the charge, he points out, because of its strong astronomy program and deep connections to Seattle鈥檚 tech community.
鈥淚f your passion is astronomy, we’ll teach you the skills needed to push the frontiers of science with flagships like Rubin,鈥 Juri膰 says. 鈥淏ut in this AI- and data-driven age, those same skills will make you competitive in other data-intensive industries as well.鈥
No matter what path they take after graduation, these students have made a lasting contribution to the exciting work at DiRAC. It’s work that will usher in a new era of astronomy and help us better understand the universe 鈥 and our place in it.