Artist’s impression of asteroid 2025 MN45. Image credit: NSF-DOE Vera C. Rubin Observatory / NOIRLab / SLAC / AURA / P. Marenfeld.
Asteroids orbiting the sun rotate at varying speeds, providing critical insights into their formation conditions billions of years ago, as well as their internal structure and evolutionary history.
Fast-spinning asteroids may have been propelled by prior collisions with other space rocks, suggesting they could be remnants of larger parent bodies.
To withstand such rapid spinning, these asteroids must possess enough internal strength to prevent fragmentation, a process where an object breaks apart due to its rotation speed.
Most asteroids consist of aggregates of debris, with their construction limiting how swiftly they can spin without disintegrating based on their density.
In the main asteroid belt, the threshold for stable fast rotation is approximately 2.2 hours. Asteroids exceeding this rotation period must be exceptionally strong to remain intact.
The faster an asteroid spins and the larger it is, the more durable its material must be.
A recent study published in the Astrophysical Journal Letters reveals important insights into asteroid composition and evolution, showcasing how the NSF-DOE Vera C. Rubin Observatory is redefining our understanding of solar system discoveries.
This research presents data on 76 asteroids with verified rotation rates.
It includes 16 ultra-fast rotators with periods ranging from approximately 13 minutes to 2.2 hours, along with three extreme rotators completing a full rotation in under 5 minutes.
All 19 newly identified high-rotation objects exceed the length of an American football field (around 90 meters).
Notably, the fastest-spinning known main-belt asteroid, 2025 MN45, has a diameter of 710 meters and completes a rotation every 1.88 minutes.
This combination establishes it as the fastest rotating asteroid discovered, surpassing 500 meters in diameter.
“Clearly, this asteroid must be composed of exceptionally strong material to maintain its structure at such high rotation speeds,” commented Dr. Sarah Greenstreet, an astronomer at NSF’s NOIRLab and the University of Washington.
“Our calculations suggest it requires cohesive forces comparable to solid rock.”
“This is intriguing because most asteroids are believed to be ‘rubble heap’ structures, composed of numerous small rocks and debris that coalesced through gravitational forces during solar system formation and collisions.”
“Discoveries like this incredibly fast-rotating asteroid result from the observatory’s unmatched ability to deliver high-resolution time-domain astronomical data, thus expanding the limits of what we can observe,” stated Regina Lameika, DOE associate director for high-energy physics.
In addition to 2025 MN45, other significant asteroids researched by the team include 2025 MJ71 (rotation period of 1.9 minutes), 2025 MK41 (rotation period of 3.8 minutes), 2025 MV71 (rotation period of 13 minutes), and 2025 MG56 (rotation period of 16 minutes).
All five of these ultra-fast rotators are several hundred meters in diameter, categorizing them as the fastest-rotating subkilometer asteroids known to date, including several near-Earth objects.
“As this study illustrates, even during its initial commissioning stages, Rubin allows us to investigate populations of relatively small, very fast-rotating main-belt asteroids that were previously unattainable,” Dr. Greenstreet concluded.
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Sarah Greenstreet et al. 2026. Light curve, rotation period, and color of the first asteroid discovered by the Vera C. Rubin Observatory. APJL 996, L33; doi: 10.3847/2041-8213/ae2a30
The Vera C. Rubin Observatory is a groundbreaking scientific facility, funded collaboratively by the NSF and the US DOE Scientific Bureau. Explore new images showcasing a glimpse of the observatory’s decade-long mission to unravel some of the universe’s greatest enigmas.
This composite image integrates 678 individual photos captured by the NSF-DOE Vera C. Rubin Observatory over a span of just over 7 hours, showcasing the Trifid (top right) and Lagoon Nebulae. Image credits: Rubinobs/Noirlab/SLAC/NSF/DOE/AURA.
The Vera C. Rubin Observatory is named in tribute to the renowned American astronomer Vera C. Rubin, who provided crucial evidence for the existence of elusive dark matter.
Investigating the characteristics of dark matter, dark energy, and other monumental cosmic phenomena is central to the observatory’s mission.
Located atop Cerro Pachón in Chile, the observatory benefits from an optimal environment with dry air and exceptionally dark skies, making it one of the world’s premier observation sites.
Equipped with an 8.4-meter telescope that houses the largest digital camera ever constructed, the facility is supported by a robust data processing system.
In the latter half of 2025, the observation deck will embark on its primary mission: a legacy study of space and time. Each night, we will systematically scan the sky, capturing every observable change.
This approach yields a detailed time-lapse record of the cosmos at ultra-high resolution.
It brings the heavens alive, revealing immense possibilities for billions of scientific discoveries.
The imagery uncovers asteroids and comets, pulsating stars, supernovae, distant galaxies, and cosmic events that have never before been documented.
“The Vera C. Rubin Observatory illustrates the United States’ commitment to leading international basic science, showcasing remarkable achievements that arise when different facets of national research collaborate,” stated an expert.
“This observatory represents an investment in our future, laying the groundwork for the knowledge that today’s youth will cultivate tomorrow.”
“The Vera C. Rubin Observatory records more data about space than all optical telescopes in history combined,” commented Dr. Brian Stone, acting NSF Director.
“Through this exceptional scientific facility, we are investigating many of the universe’s mysteries, including the enigmatic dark matter and dark energy that fill our cosmos.”
“We are entering a golden era of American science,” remarked Dr. Harriet Kang, acting director of the DOE’s Department of Science.
“The Rubin Observatory symbolizes what can be accomplished when the federal government endorses a tool that leads world-class engineers and scientists.”
“This facility will propel discovery, inspire future innovators, and unleash America’s scientific excellence.”
The Rubin Observatory is also the most efficient solar system discovery tool ever created.
It captures approximately 1,000 images of the southern hemisphere sky each night, enabling a complete survey of the visible southern sky every three to four nights.
This capability will assist millions in detecting hidden asteroids, comets, and interstellar objects.
The observatory represents a paradigm shift in planetary defense, helping to identify potential threats to Earth or the Moon.
“The unveiling of the first images from the observatory heralds a new era in astrophysics,” remarked Dr. Patrick McCarthy, director of NSF’s NOIRLab.
“We congratulate the Rubin Observatory team on this monumental accomplishment and anticipate the initiation of a legacy study of space and time that may transform our comprehension of the universe.”
Countless unique asteroids traverse the solar system, amidst millions of distant stars and galaxies captured in the inaugural images released by the Vera C. Rubin Observatory.
“These stunning galaxies were photogenically disrupted by asteroids,” noted Željko Ivezić during a press briefing on June 23rd at Washington University in Seattle, presenting images that showcase several asteroids zipping past two spiral-armed galaxies.
Within just 10 hours of observing the night sky, the telescope, positioned in the pristine atmosphere atop a mountain in the Chilean desert, detected 2,104 previously unknown asteroids. Among these, seven have trajectories that come close to Earth, yet none poses a threat, according to Ivezic.
Researchers identified and tracked newly discovered asteroids in images taken over 10 hours
NSF-DOE VERA C. RUBIN OBSERVATORY
Although telescopes are not primarily designed to detect near-Earth objects, they are intended for a comprehensive study of the universe over a decade. However, their features are also conducive to spotting asteroids. “You need to survey the sky rapidly with a vast field of view,” Ivezic explained.
Asteroids were identified by scrutinizing areas of the sky and noting what was in motion. In the composite image shown by Ivezić during the briefing, the asteroids appeared as colored streaks against the backdrop of brighter objects in deeper space. This enhances our understanding of the neighboring celestial bodies. “We weren’t surprised,” he said. “There’s an impressive simulation.”
Throughout a decade-long research initiative, the telescope is anticipated to identify around 5 million new asteroids, surpassing the total discovered in previous centuries.
Asteroids are marked with a colored dot in front of an image of a galaxy visible in the southern sky
NSF-DOE VERA C. RUBIN OBSERVATORY Copyright: NSF-DOE VERA C. Rubin Observatory
The new detections are reported daily to the US Minor Planet Center, which analyzes orbital paths and identifies objects that could threaten Earth. “In under 24 hours, the world will be informed about potentially hazardous objects,” Ivezic stated.
Matthew Payne from the Minor Planet Center remarked that it’s estimated only 40% of close Earth objects capable of posing a threat have been discovered. An exponential increase in detections from the Vera Rubin Observatory will hasten the identification of the remaining objects.
A substantial rise in observations of other solar system entities—from main belt asteroids between Mars and Jupiter to objects further out beyond Neptune—is anticipated to offer fresh insights into our immediate cosmic neighborhood. “It’s expected to truly revolutionize solar system science,” Payne concluded.
Trifid (top right) and Lagoon (center) nebula view from Vera C. Rubin Observatory
NSF-DOEVERA C. Rubin Observatory
The stunning pink and blue regions of this stellar nursery, along with dense clusters of surrounding galaxies, mark the initial insights from the Vera C. Rubin Observatory.
These images were crafted from about 10 hours of observations atop Chile’s Celopachen Mountain, serving as tests to illustrate the types of captures Rubin can produce. The telescope’s extensive mission to monitor the night sky, recognized as a legacy study of space and time, is set to commence later this year.
The initial image (above) showcases the Trifid Nebula, a striking pink and blue formation located in the upper right corner, where numerous young stars emerge from a star-forming region. At the image’s center lies the Lagoon Nebula, a large expanse of interstellar gas and dust. To create this visual, astronomers amalgamated 678 individual photographs taken by Rubin over a span of seven hours.
A close-up of the full Virgo cluster as seen from Vera C. Rubin Observatory
NSF-DOEVERA C. Rubin Observatory
The subsequent image focuses on the Virgo cluster, a composition of thousands of galaxies recognized by astronomers for ages. While the brightest members are visible through a basic telescope, Rubin’s detailed capture presents the entire cluster and its surrounding galaxies. For a more comprehensive view, check out the full zoom-out image showcased in the video below, which reveals around 10 million galaxies.
These represent only 0.5% of the 20 billion galaxies that Rubin will observe throughout its lifespan, assisting in unraveling the enigmas of dark matter and exploring the potential for a mysterious ninth planet within our solar system.
Observatory photos will be unveiled during the live stream today at 4 PM (11 AM EDT).
I’ve never attended a watch party, unless you include a gathering with my two friends for the Taylor Swift: ERAS Tour (which featured themed snacks). But now, it seems watch parties are evolving beyond just movie releases. In fact, I’m gearing up to join a watch party for my new telescope in just a few days.
I was fortunate enough to be part of one of the first public groups to tour the Bella C. Rubin Observatory in Chile, a visit organized by New Scientist. Now, just two years later, I’m eagerly anticipating the first image that will be captured by this colossal telescope, scheduled for release on June 23rd.
The Vera C. Rubin Observatory stands as a marvel of engineering. It’s set to perform sky scans across the Southern Hemisphere within merely three nights. Over a decade, the observatory will conduct scans for ten nights as part of its legacy survey of space-time known as the LSST. This project promises to revolutionize our understanding of astronomy, unraveling longstanding mysteries, including those related to dark matter, and revealing new enigmas.
Clearly, the images and videos produced by the telescope will be breathtaking. To fully appreciate their detail, watching on a phone screen won’t suffice. Even a desktop display falls short. To capture the full glory of a single image, one would need to utilize 400 Ultra HD TVs, as per the LSST UK consortium. Consequently, the team is encouraging partner institutions worldwide to organize watch parties for a more immersive viewing experience.
The specifics of each watch party vary depending on the hosting institution, which may include planetariums, museums, or universities. For instance, events will take place at the Perth Observatory in Australia and at City University in Hong Kong. Numerous locations across the United States, including the Detroit Observatory in Michigan, will host watch parties where attendees can enjoy science demos and hear from local experts. A common thread across all these events is the live release of the first images and videos captured by the Vera C. Rubin Observatory at 11 AM EDT (11 PM GMT), with everyone tuning in to the live stream.
Processing the intricate details of each image can be a time-consuming endeavor. Not only is there the requirement to zoom out and appreciate the telescope’s expansive field of view, but also to zoom in on galaxies in unprecedented detail. Images produced by Rubin will offer greater resolution than those from the James Webb Space Telescope, covering similar sky areas with 45 moon-like objects while JWST operates with roughly three years of data. Additionally, a time-lapse video capturing how the sky evolves over time has been recorded by Rubin.
You’ll indeed be able to view the images online, as well as in issues of New Scientist once they’re published or shared on social media. However, if you want to celebrate this moment in a community setting, consider visiting this interactive map to discover a watch party near you—or, why not host one yourself? While you may miss the full definition on your home screen, you can still experience some of the thrill of witnessing the unveiling of these images and videos alongside others.
I’m excited to attend a local event, hoping to capture the sense of wonder I felt when I first stood inside the observatory and marveled at its grandeur. It’s a scale that helps us better understand our place in the cosmos, even when contrasted with the vastness of the universe.
The Vera C. Rubin Observatory is set to provide a new perspective on the universe
Olivier Bonin/SLAC National Accelerator Laboratory
The elevation is high above Celopachen, a Chilean mountain towering over 2600 meters. As I ascend the stairs within the dome of the Vera C. Rubin Observatory, I find myself breathing deeply. The atmosphere is cool, serene, and expansive, resembling a cathedral. Then, the entire dome begins to rotate, revealing the vast sky.
Night falls, unveiling an abundance of stars like I’ve never witnessed. The Milky Way shines exceptionally bright, and I can spot two of its satellite galaxies, the Small Magellanic Cloud. Yet, the Rubin telescope steals the show with its massive presence. It boasts the largest digital cameras and lenses in the world, tipping the scales at a staggering 350 tons. As a reflective telescope, it gathers light via a mirror, with its largest mirror measuring 8.4 meters across. The tunnel leading to the summit matches its width at about 8.5 meters.
Despite its immense weight, this telescope can maneuver swiftly, poised to transform our understanding of the solar system, galaxies, and the universe at large. Every three nights, it completes a Southern Sky survey, a feat that previously required weeks or months. Over a decade, Rubin will create a kind of cosmic time-lapse.
“By capturing the sky every three days, we can layer those images to delve deeper,” explains researcher Kevin Rail. “Ten years down the line, we will have explored much more deeply, revealing the universe’s structure,” he states.
A core mission of the observatory involves comprehensively understanding how dark matter influences the cosmos. Bella Rubin, the namesake astronomer, initiated this journey in the 1970s when observations of galaxy rotation disclosed that visible matter represented only a fraction of the universe. She discovered that stars on the galactic outskirts were moving faster than expected; according to Kepler’s Law, they should be traveling more slowly compared to stars nearer the galaxy’s center.
After extensive observations and calculations, it became evident that additional unseen mass must exist. This invisible entity is referred to as dark matter, and astronomers now estimate that it is nearly five times more abundant than visible matter, exerting gravitational effects that shape our observable universe.
“Visible entities are actually following the contours set by dark matter, not vice versa,” observes Stephanie Deppe at the observatory. Galaxies are believed to be arranged in what astronomers term the cosmic web, woven by filaments of dark matter that hold the visible stars through gravity. The images captured by Rubin provide an unprecedented view of this web.
Mapping this web also aids in uncovering the properties of dark matter. Is it composed of fast-moving, lightweight particles or is it cold and denser? “You can identify small anomalies, such as kinks in a stellar stream,” Deppe adds. These anomalies indicate where dark matter has accumulated along the filaments. Determining the mass will help to refine hypotheses regarding the type of dark matter present. Additionally, the structure of the cosmic web offers insights into dark energy, the force propelling the universe’s expansion.
Staff at the summit installing the Vera C. Rubin Observatory’s Commissioning Camera in August 2024.
Rubin Observatory/NSF/AURA/H. Stockebrand
The excitement surrounding precision astronomy is palpable at the observatory. During the evening’s observations, chatter fills the kitchen near the telescope control room. One of the telescope operators bounces with eagerness: “We hope the skies cooperate tonight,” a term used for opening the telescope’s shutter to capture images. “Indeed, we do,” his colleague responds, smiling over a cup of tea. As the sun sets, we collectively wish for a clear evening.
When the clouds part, the control room buzzes with activity. The operator skillfully adjusts the telescope to ensure proper focus. Every 30 seconds, a new image is captured, and an audio cue signals when the shutter opens and closes, followed by a satisfying whoosh as it resets. The telescope snaps a segment of the sky before dashing to the next location, creating a grid that will be stitched together.
All systems run smoothly until suddenly, a glitch arises. To optimize viewing opportunities, the observatory employs an automated system that determines where the telescope should aim, based on weather conditions and moon phases. However, this system has momentarily malfunctioned. Operators traverse the mountains for hours with scientists at base camp, diving into the code to locate the problem. Twenty minutes later, adjustments are made, and the regular shutter cadence resumes, with images flowing in once more.
“This is one of the best nights we’ve experienced. The data is exceptional,” notes Eli Rikov, Calibration Scientist. “I hope the processors can deliver high-quality scientific images.”
Once captured, the images embark on a swift journey around the globe. They traverse the 103,000 km stretch of fiber cables leading either across the Atlantic or Pacific, ultimately reaching the U.S. The images pass through a hub in Florida before arriving at the SLAC National Accelerator Laboratory in California.
Each image is approximately 32 gigapixels, comparable to a 4K movie, and arrives within about 10 seconds. William Omlan manages data on the observation deck. From there, the data is distributed to facilities in the UK and France, making the images accessible to scientists worldwide.
One of the most urgent analyses will focus on swiftly moving objects. The night sky constantly shifts and changes in unpredictable ways, and the Rubin Observatory is poised to catch these movements. It will track asteroids and comets moving across the sky, including those in the main asteroid belt between Mars and Jupiter, as well as Trans-Neptunian objects.
“Currently, we only know a few thousand objects,” explains an expert in the Kuiper Belt and other distant clouds. “Rubin could potentially increase our catalog tenfold.”
Moreover, it will help monitor potential threats from near-Earth objects, amplifying our known inventory from around 30,000 to approximately 100,000. The telescope has also successfully observed fast-moving interstellar visitors like Oumuamua, which zipped through our solar system in 2017, and Borisov, which arrived in 2019.
This census of solar system objects could also shed light on the elusive Planet 9, a hypothetical world—5 to 10 times Earth’s size—believed to exist in the outer solar system, inferred from the unusual orbits of Kuiper Belt objects. Simulations suggest it could be responsible, though conclusive evidence is still missing.
That may soon change. “Rubin might directly discover Planet 9, providing definitive proof or debunking its existence,” Deppe mentions.
One mystery the telescope won’t unravel is the uncertain future of American scientific funding. Jointly funded by the U.S. Department of Energy and the National Science Foundation (NSF), the latter has faced proposed budget cuts exceeding 50%. When I inquired about its implications, staff at the observatory were uncertain. “I won’t speculate about the potential impact of the President’s fiscal year 2026 budget request,” an NSF spokesperson responded.
But inside the control room, funding debates can wait. Though midnight approaches, shifts are far from over. Scientists work diligently until 3 or 4 a.m., but weariness seems absent. Every so often, someone exclaims, “Look at these stunning images!”
The first publicly released image appeared on June 23rd, capturing a full view of the southern sky every three nights. “The entire idea is to construct an observatory capable of collecting all the data demanded by the scientific community worldwide.”
Vera C. Rubin Observatory is set to unveil new perspectives of the universe
Olivier Bonin/SLAC National Accelerator Laboratory
The atmosphere above Celopachen, a mountain in Chile standing over 2600 meters high, is sparse. Taking a trip up the stairs inside the dome of the Vera C. Rubin Observatory requires a breath. It’s cool, serene, immensely spacious—and then the entire dome rotates, revealing the sky.
As night envelops the landscape, the stars multiply, more abundant than I’ve ever witnessed. The Milky Way glows vibrantly, and I spot the small Magellanic Cloud, one of our galaxy’s companions. The Rubin telescope, however, dominates the scene—it’s massive, boasting the world’s largest digital cameras and lenses, with a weight of 350 tonnes. This reflective telescope gathers light through its mirror, with the largest mirror measuring 8.4 meters in diameter, designed to fit snugly through the 8.5-meter wide tunnel leading to the summit.
Despite its impressive heft, the telescope is swift, poised to transform our understanding of our solar system, galaxies, and the universe. Every three nights, it captures a survey of the Southern Sky. While previous sky investigations took weeks or months, Rubin accomplishes this in just half the time, providing a sort of cosmic time-lapse.
“By photographing the sky every three days, we can layer those images to delve deeper,” explains scientist Kevin Rail. “Thus, a decade from now, you’ll delve into the universe’s inner workings and its structure,” he adds.
Unraveling that structure is among the observatory’s goals, focusing on how dark matter distorts the universe. Bella Rubin, the namesake astronomer, pioneered this quest in the 1970s through galaxy rotation observations that indicated visible matter was but a fraction of what exists. She noted that stars at a galaxy’s edge were zipping by too quickly, contradicting Kepler’s Law, which suggested they should move at slower velocities compared to those near the galactic center.
After extensive observation and calculations, the conclusion was clear: an unseen entity must be present—this is now known as dark matter. Astronomers believe it comprises nearly five times more mass than visible matter, and its gravitational pull shapes the universe we observe.
“Visible matter actually traces dark matter’s gravitational field, not the other way around,” says Stephanie Deppe at the observatory. Galaxies are perceived to exist in what astronomers term the cosmic web, interlinked by dark matter filaments that capture the stars we can observe. Rubin’s images offer unparalleled views of this web.
This mapping effort aids in deciphering dark matter’s nature—whether it’s composed of hot, light, fast-moving particles or colder, aggregated ones. “We seek small disturbances, like kinks in stellar streams,” Deppe explains. These disturbances indicate sections where dark matter is concentrated within filaments. Understanding the mass from these observations refines our knowledge of dark matter’s characteristics. Moreover, deciphering the cosmic web’s structure can enhance our comprehension of dark energy, the force accelerating the universe’s expansion.
Summit staff will install the Vera C. Rubin Observatory’s commissioning camera in August 2024.
Rubin Observatory/NSF/AURA/H. Stockebrand
The enthusiasm for precision astronomy is palpable at the observatory. During my observation night, excitement buzzes through the air, particularly in the kitchen adjoining the control room. One of the operators, practically bouncing with energy, exclaims, “We hope the sky is clear tonight!” This term refers to opening the telescope shutter for imaging. “Indeed, we do,” replies a colleague, grinning over their tea. As twilight descends, we all hope for a cloudless sky.
When the clouds part, the control room buzzes with energy. An operator continues fine-tuning the telescope for optimum image focus. Every 30 seconds brings a new image, followed by the sound of the shutter opening and closing—like a hushed reverberation through the dome as it swiftly captures and moves on to the next section of the sky, constructing an intricate cosmic puzzle.
Suddenly, an unexpected glitch occurs. To maximize observational efficiency, the observatory employs an automated program that directs the telescope based on weather and moon phases, but this system stumbles momentarily. Operators venture through the rugged terrain alongside scientists at base camp, collaborating to troubleshoot the issue. After about 20 minutes, adjustments are made, and normal operations resume, with the rhythm of the shutter beginning anew.
“This is one of our best nights; everything is flowing smoothly—this data is excellent,” reveals Eli Rikov, the calibration scientist. “I’m optimistic the processors will produce high-quality scientific images.”
Once captured, images embark on a rapid journey around the globe. They traverse down the mountain on an extensive network of 103,000 km of fiber optic cables, reaching the Atlantic or Pacific Oceans before arriving in the US. Images pass through a central hub in Florida before arriving at the SLAC National Accelerator Laboratory in California.
Each captured image consists of about 32 gigapixels, roughly the equivalent of a 4K movie, and they arrive in approximately 10 seconds. William Omlan, overseeing data on the observation deck, then disseminates this data to facilities in the UK and France, ensuring it reaches scientists worldwide.
Most urgent analyses focus on rapidly moving celestial bodies. The night sky is in constant flux, exhibiting blips and changes in unpredictable patterns. The Rubin Observatory is uniquely equipped to capture these dynamic movements, allowing for near-real-time detection of rapidly changing objects. The telescope tracks asteroids and comets racing across the night sky, including those within the asteroid belt between Mars and Jupiter, as well as trans-Neptunian objects.
“Currently, we are aware of thousands of these objects,” says the Kuiper Belt and Oort Cloud researcher. “Rubin will likely increase that count tenfold.”
The observatory also plays a crucial role in monitoring potential threats from near-Earth objects, aiming to expand our knowledge from about 30,000 to an estimated 100,000. It has even succeeded in capturing fast-moving interstellar objects, such as Oumuamua, which passed through our solar system in 2017, and Borisov, which followed in 2019.
This extensive census of the solar system might also solve the enigma of Planet 9. Intriguing evidence suggests a body—5 to 10 times the mass of Earth—exists in the outer solar system, inferred from Kuiper Belt objects exhibiting peculiar yet similar orbits. Simulations propose that such a planet could be influencing these orbits, though direct evidence remains elusive.
That may soon change. “Rubin’s data will either uncover definitive evidence of Planet 9 or eliminate any existing doubts,” predicts Deppe.
However, there’s also uncertainty looming over American science funding. The observatory receives joint funding from the US Department of Energy and the National Science Foundation (NSF), the latter having faced draconian budget cuts proposed by over half. When I inquired about the potential implications, staff members seemed nonplussed. “I prefer not to speculate on the effects of the President’s budget request for fiscal year 2026,” an NSF spokesperson told me later.
For now, though, back in the control room, financial concerns take a backseat. Approaching midnight, the shift continues. Scientists work diligently until 3 am or 4 am, yet fatigue seems nonexistent. Occasionally, someone brightens the room with, “Look at these stunning images!”
The first published image emerged on June 23rd, showcasing a complete view of the southern sky obtained every three nights. “The vision is to create an observatory that can capture all the data the world wishes for.”
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