Latest news with #CosmicDawn
Time of India
7 days ago
- Science
- Time of India
13-Billion-year-old ‘Cosmic Dawn' signal captured by ground-based telescope: A breakthrough in tracing the origins of universe
In a rare and remarkable scientific achievement, scientists have detected a 13-billion-year-old microwave signal from a period known as the Cosmic Dawn. It is a time just after the Big Bang when the first stars and galaxies began to form. What makes this achievement remarkable is that the signal was picked up not from space, but using Earth-based telescopes situated at high altitudes in the Andes mountains of northern Chile. The discovery was made by astrophysicists from the CLASS (Cosmology Large Angular Scale Surveyor) project. The project is funded by the US National Science Foundation. These weak signals of polarised microwave radiation provide rare insights into the early universe and reveal how the first cosmic structures influenced light leftover from the Big Bang. This is the first time such a faint and ancient signal has been observed from the ground. The breakthrough was achieved by the team led by Professor Tobias Marriage of Johns Hopkins University (JHU). This major feat defies previous assumptions that these signals could only be detected using space telescopes, due to the many technological and environmental obstacles faced by ground observatories. What is the Cosmic Dawn that sent the 13-billion-year-old signal The Cosmic Dawn refers to the time period between roughly 50 million and one billion years after the Big Bang. This is the period when the first stars, galaxies, and black holes began to form. It was like a dawn for the Universe. Before this phenomena, the universe was in a dark, neutral state with no sources of light. The earliest stars also known as Population III stars ignited nuclear fusion and emitted intense ultraviolet radiation that lit up the universe and began the process of reionization. This radiation ionized the surrounding hydrogen gas which allow light to travel freely through space for the first time. by Taboola by Taboola Sponsored Links Sponsored Links Promoted Links Promoted Links You May Like Giao dịch vàng CFDs với sàn môi giới tin cậy IC Markets Tìm hiểu thêm Undo During this era, small, irregular galaxies started to assemble, and early black holes likely formed from the collapse of massive stars. These events fundamentally changed the nature of the cosmos. By studying light from this time, such as polarised microwave signals left on the cosmic microwave background, scientists can learn how the first luminous objects shaped the universe's structure. The Cosmic Dawn marks the universe's transition from darkness to light and holds key insights into how modern galaxies, including our own- Milky way, came to be. Why detecting this signal is so difficult and significant The microwaves that scientists are looking for from the Cosmic Dawn are extremely faint. It is about a million times weaker than regular cosmic microwave background radiation. These polarised microwave signals are measured in mere millimetres of wavelength and are easily drowned out by earthly interference such as radio broadcasts, radar signals, satellites, and even atmospheric conditions like humidity or temperature shifts. According to researchers, even under ideal conditions, detecting these signals requires highly sensitive and precisely calibrated instruments. CLASS telescopes were custom-designed for this task and strategically placed in high-altitude regions of Chile, where the thinner, drier air provides a clearer view of the universe. How the CLASS team overcome the odds: A first feat from Earth 'People thought this couldn't be done from the ground,' said Prof. Tobias Marriage. 'Astronomy is a technology-limited field, and microwave signals from the Cosmic Dawn are famously difficult to measure. Ground-based observations face additional challenges compared to space. Overcoming those obstacles makes this measurement a significant achievement.' The CLASS team addressed these challenges by cross-referencing their data with results from previous space missions, such as NASA's Wilkinson Microwave Anisotropy Probe (WMAP) and the European Space Agency's Planck telescope. By identifying and eliminating interference, they were able to isolate a consistent signal from the polarised light. It confirmed that it originated from the early universe. The polarised microwave light Light becomes polarised when it bounces off surfaces or particles, causing the waves to align in a particular direction. A simple example is sunlight reflecting off a car hood, which creates a glare—one that can be reduced with polarised sunglasses. Similarly, ancient cosmic light that interacted with early matter became polarised. 'Using the new common signal, we can determine how much of what we're seeing is cosmic glare from light bouncing off the hood of the cosmic dawn, so to speak,' explained Dr. Yunyang Li, one of the study's co-authors and a researcher affiliated with Johns Hopkins and the University of Chicago. New path to explore the origins of the universe The CLASS project has opened a powerful new window into understanding the origins of the universe. The study of these signals can help scientists to see how the first light sources interacted with matter. They can trace how early stars triggered the formation of galaxies. These processes shaped large-scale structures that still define the universe today. This research opens the door to new discoveries. It gives scientists a roadmap to explore the earliest and most mysterious parts of the universe without relying only on space missions. It proves that advanced ground-based technology, when combined with clever methodology and favourable locations, can rival even space telescopes in tracing the earliest chapters of cosmic history. This research validates the capabilities of Earth-based astronomy and paves the way for deeper studies into the birth of stars, the formation of galaxies, and the evolution of the universe itself.
Indian Express
12-06-2025
- Science
- Indian Express
Scientists detect 13 billion-year old signal from ‘Cosmic Dawn' using Earth-based telescopes
In what can be called a truly unique accomplishment, scientists seem to have detected a 13 billion-year-old signal using Earth-based telescopes. This feat allow them to see how the first stars impacted light emitted from the Big Bang. Astrophysicists measured polarised microwave light to create a clearer picture of what is known as Cosmic Dawn. They traced this by using telescopes high in the Andes mountains of northern Chile. Cosmic Dawn refers to the period roughly between 50 million to one billion years after the Big Bang, a time when the first stars, black holes, and galaxies were reportedly formed. The research led by Tobias Marriage, professor of physics and astronomy at Johns Hopkins University (JHU), is the first time ground-based observations have captured signals from the Cosmic Dawn. 'People thought this couldn't be done from the ground. Astronomy is a technology-limited field, and microwave signals from the Cosmic Dawn are famously difficult to measure,' Marriage was quoted as saying by the JHU website. 'Ground-based observations face additional challenges compared to space. Overcoming those obstacles makes this measurement a significant achievement,' he added. According to the official JHU website, cosmic microwaves are barely millimetres in wavelength and are very hard to detect. The signal from polarised microwave light is about a million times fainter, making it much more difficult to trace. Meanwhile, on Earth, broadcast radio waves, radar and satellites can drown their signal, and changes in the atmosphere, weather and even temperature can distort it. The researchers claimed that even under perfect conditions, measuring this type of microwave would need highly sensitive equipment. Scientists from the US National Science Foundation's Cosmology Larger Angular Scale Surveyor, or CLASS project, used telescopes that have been specifically designed to detect traces left by the first stars in the relic big bang light. This was previously only accomplished by technology deployed in space, such as the US National Aerospace and Space Administration Wilkinson Microwave Anisotropy Probe (WMAP) and European Space Agency Planck space telescopes. As part of the project, the researchers compared the CLASS telescope data with data from the Planck and WMAP missions. They identified interference and narrowed in on a common signal from the polarised microwave light. Polarisation is when light waves collide into something and scatter. 'When light hits the hood of your car and you see a glare, that's polarisation. To see clearly, you can put on polarised glasses to take away glare,' said author Yunyang Li, who was a PhD student at Johns Hopkins and then a fellow at the University of Chicago during the research. 'Using the new common signal, we can determine how much of what we're seeing is cosmic glare from light bouncing off the hood of the cosmic dawn, so to speak.'
Yahoo
12-06-2025
- Science
- Yahoo
The Universe's Largest Map Has Arrived, And You Can Stargaze Like Never Before
After many hours of staring unblinking at a small patch of sky, JWST has given us the most detailed map ever obtained of a corner of the Universe. It's called the COSMOS-Web field, and if that sounds familiar, it's probably because an incredible image of it dropped just a month ago. That, however, was just a little taste of what has now come to pass. The full, interactive map and all the data have just dropped, a map that vastly outstrips the famous Hubble Ultra Deep Field's 10,000 galaxies. The new map contains nearly 800,000 galaxies – hopefully heralding in a new era of discovery in the deepest recesses of the Universe. "Our goal was to construct this deep field of space on a physical scale that far exceeded anything that had been done before," says physicist Caitlin Casey of the University of California Santa Barbara, who co-leads the COSMOS collaboration with Jeyhan Kartaltepe of the Rochester Institute of Technology. "If you had a printout of the Hubble Ultra Deep Field on a standard piece of paper, our image would be slightly larger than a 13-foot by 13-foot-wide mural, at the same depth. So it's really strikingly large." JWST is our best hope for understanding the Cosmic Dawn, the first billion or so years after the Big Bang, which took place around 13.8 billion years ago. This epoch of the Universe is extremely difficult to observe: it's very far away, and very faint. Because the Universe is expanding, the light that travels to us from greater distances is stretched into redder wavelengths. With its powerful resolution and infrared capabilities, JWST was designed for just these observations: finding the faint light from the dawn of time which informs us on the processes that gave rise to the Universe we see around us today. The COSMOS-Web image covers a patch of sky a little bigger than the area of 7.5 full Moons, and peers back as far as 13.5 billion years, right into the time when the opaque primordial fog that suffused the early Universe was beginning to clear. There, the researchers are looking not just for early galaxies, they're looking for an entire cosmic ecosystem – an interactive gravitational dance of objects bound by the cosmic web of dark matter that spans the entire Universe. JWST data collected to date indicates that even with Hubble data, we've barely scratched the surface of what lurks within the Cosmic Dawn. "The Big Bang happens and things take time to gravitationally collapse and form, and for stars to turn on. There's a timescale associated with that," Casey says. "And the big surprise is that with JWST, we see roughly ten times more galaxies than expected at these incredible distances. We're also seeing supermassive black holes that are not even visible with Hubble." This profusion of well-formed galaxies hasn't just surprised astronomers – it's given them a whopping great puzzle to solve. According to our current understanding of galaxy evolution, not enough time had elapsed since the Big Bang for them to have formed. Even one is a bit of a head-scratcher – but the numbers in which JWST is finding them just boggle the mind. With access to datasets free and available to everyone who wants to take a crack, however, we may get a few answers. "A big part of this project is the democratization of science and making tools and data from the best telescopes accessible to the broader community," Casey says. "The best science is really done when everyone thinks about the same data set differently. It's not just for one group of people to figure out the mysteries." Papers on the data have been submitted to the Astrophysical Journal and Astronomy & Astrophysics. Meanwhile, you can head over to the COSMOS-Web interactive website and muck about zooming through the Universe nearly all the way back to the beginning of time. Giant Jets Bigger Than The Milky Way Seen Shooting From Black Hole Humanity Has Just Glimpsed Part of The Sun We've Never Seen Before 'City-Killer' Asteroid Even More Likely to Hit The Moon in 2032
Digital Trends
12-06-2025
- Science
- Digital Trends
Webb Telescope gets the star treatment in new NASA documentary
The pages of Digital Trends are filled with breathtaking images of deep space captured by the James Webb Space Telescope, including the beautiful Cosmic Tornado, the gorgeous Ring Nebula, the incredible Carina Nebula, and a stunning spiral galaxy. The Webb telescope — the most powerful ever built — launched in 2021 and has been scanning the far reaches of space ever since. Besides beaming back amazing infrared imagery, the telescope is also helping scientists to learn more about the universe's first stars and galaxies, the formation of numerous stars and planetary systems, and the origins of life itself, by exploring distant places with unprecedented clarity. To celebrate the ongoing work of the Webb telescope, NASA has just released a documentary — Cosmic Dawn — that chronicles its more than two decades of development, highlighting the telescope's careful assembly, rigorous testing, and successful launch nearly five years ago. Cosmic Dawn has a runtime of 96 minutes and is free to watch on YouTube. We've embedded it at the top of this page. 'At NASA, we're thrilled to share the untold story of our James Webb Space Telescope in our new film Cosmic Dawn, celebrating not just the discoveries, but the extraordinary people who made it all happen, for the benefit of humanity,' said Rebecca Sirmons, head of NASA+. The documentary also offers viewers an inside look at the successes and setbacks experienced by the team at NASA's Goddard Space Flight Center in Greenbelt, Maryland — the birthplace of Webb. You'll also get to enjoy plenty of Webb's groundbreaking work, including remarkable images of the faint light of the first stars and galaxies that formed more than 13.5 billion years ago. The documentary also shares Webb's findings on black holes, planets in our solar system and far beyond, and plenty of other cosmic phenomena. 'Webb was a mission that was going to be spectacular whether that was good or bad — if it failed or was successful,' said video producer Sophia Roberts, who filmed some of the happenings prior to Webb's deployment. Roberts added: 'It was always going to make history.'
NDTV
12-06-2025
- Science
- NDTV
Scientists Observe Light Of "Cosmic Dawn" With Telescope On Earth For The First Time Ever
Astronomers have used Earth-based telescopes to observe "Cosmic Dawn", which is the early period in the universe's history, around 800 million years after the Big Bang, when the first stars and galaxies formed, emitting light that ended the cosmic dark ages. This era was a significant milestone in the universe's evolution as massive stars and galaxies were formed and the universe's structure and composition were shaped. Scientists have used James Webb Space Telescope (JWST) observations of distant galaxies to get insights into the cosmic dawn. Computational models also help understand galaxy formation and evolution. "People thought this couldn't be done from the ground. Astronomy is a technology-limited field, and microwave signals from the Cosmic Dawn are famously difficult to measure," team leader and Johns Hopkins professor of physics and astronomy, Tobias Marriage, said in a statement. "Ground-based observations face additional challenges compared to space. Overcoming those obstacles makes this measurement a significant achievement," Marriage added. Cosmic dawn insights shed light on the universe's early stages, providing an understanding of the universe's origins. The scientists were able to get a new glimpse of Cosmic Dawn using the Cosmology Large Angular Scale Surveyor (CLASS), which is an array of telescopes located high in the Atacama Desert region of Northern Chile. The main objective of CLASS is to observe the Cosmic Microwave Background (CMB), which is a cosmic fossil left over from an event just after the Big Bang. The changes in the atmosphere, weather and temperature can distort the light, broadcast radio waves, radar, and satellites can access their signal on Earth. The light from Cosmic Dawn is extremely faint as the wavelength is in millimetres, which is obvious as it has travelled to us for 13 billion years and more. The signal from polarised microwave light is about a million times fainter. Polarisation means the orientation of oscillations or vibrations in a wave, such as light or electromagnetic waves. This can happen when light hits an object and scatters off it. "When light hits the hood of your car and you see a glare, that's polarization. To see clearly, you can put on polarized glasses to take away glare," said team member Yunyang Li, who was a PhD student at Johns Hopkins. "Using the new common signal, we can determine how much of what we're seeing is cosmic glare from light bouncing off the hood of the Cosmic Dawn, so to speak," added Yunyang, who was a fellow at the University of Chicago while this research was being conducte
