NASA, ESA, CSA, STScI, J. Lee (STScI), T. Williams (Oxford), PHANGS Team
This Webb image shows a densely populated spiral galaxy anchored by a central region that has a light blue haze, known NGC 628. It's 32 million light-years away in the constellation Pisces.
NASA/ESA/CSA/ STScI
In this new image of Uranus, the planet shines shine brightly, along with its many rings and moons.
NASA/ESA/CSA/STScI
The James Webb Space Telescope's shot of supernova remnant Cassiopeia A shows elaborate details visible for the first time.
NASA/ESA/CSA/STScI
There are approximately 500,000 stars in this image of the Sagittarius C region of the Milky Way. The bright cyan area contains emissions from ionized hydrogen.
NASA/ESA/CSA/STScI
Galaxy cluster MACS0416 is seen here in exquisite detail thanks to a composite image created with data from both NASA's James Webb and Hubble space telescopes.
NASA/ESA/CSA/STScI/Tea Temim
Scientists are hoping to gain more information about the origins of the Crab Nebula, thanks to new details spotted by the James Webb Space Telescope.
ESA/Webb/NASA/CSA
This image shows the Ring Nebula in exceptional detail, like the filament elements in the ring's inner section.
NASA/ESA/CSA
Earendel, the most distant star ever discovered, can be seen in this image of the Sunrise Arc galaxy.
NASA/ESA/CSA/JWST Ring Nebula Team
The Ring Nebula is seen in breathtaking detail, in a composite image released on August 4.
J. DePasquale/CSA/ESA/NASA
The James Webb Space Telescope captured a high-resolution image of a pair of actively forming stars called Herbig-Haro 46/47. The stellar duo, only a few thousand years old, is located at the center of the red diffraction spikes.
NASA/ESA/CSA/Klaus Pontoppidan, STScI
The James Webb Space Telescope captured a detailed closeup of the birth of sunlike stars in the Rho Ophiuchi cloud, the closest star-forming region located 390 light-years from Earth. The young stars release jets that cause the surrounding gas to glow. The image's release marks the first anniversary of Webb's observations of the cosmos.
NASA
Saturn and its moons were captured by NASA's James Webb Space Telescope June 25. The image shows details of the planet's atmosphere and ring system.
ESA/Webb/NASA/CSA
The James Webb Space Telescope captured the Orion Bar, a part of the Orion Nebula that is being eroded by stellar radiation emanating from the Trapezium Cluster.
NASA/ESA/CSA
This composite image, shot from the James Webb Space Telescope's MIRI and NIRCam instruments, shows the bright clusters of stars and dust from barred spiral galaxy NGC 5068.
NASA/ESA/CSA/STScI
Webb captured a burst of star formation triggered by two colliding spiral galaxies called Arp 220. The phenomenon is the closest ultra-luminous galactic merger to Earth.
NASA/ESA/CSA/A. Pagan/A. Gáspár
Dusty rings surround Fomalhaut, a young star outside of our solar system that's 25 light-years from Earth.
NASA/ESA/CSA/STScI/Webb ERO Production Team
The Wolf-Rayet star WR 124 was one of the James Webb Space Telescope's first discoveries, spotted in June 2022.
NASA/ESA/CSA/D. D. Milisavljevic/T. Temim/I. De Looze
Stunning details can be seen in this Webb telescope photo of supernova remnant Cassiopeia A, which is 11,000 light-years from Earth.
Space Telescope Science Institut/STScI
Webb's image of ice giant Uranus shows off the planet's incredible rings and a bright haze covering its north polar cap (right). A bright cloud lies at the cap's edge and a second one is seen at left.
NASA/ESA/CSA/STScI
The James Webb Space Telescope captured 50,000 sources of near-infrared light in a new image of Pandora's Cluster, a megacluster of galaxies. The cluster acts like a magnifying glass, allowing astronomers to see more distant galaxies behind it.
NASA/ESA/CSA
Stars shine through the hazy material of the Chamaeleon I dark molecular cloud, which is 630 light-years away from Earth.
NASA/ESA/CSA/STScI/A. Pagan
The James Webb Space Telescope spotted NGC 346, one of the most dynamic star-forming regions near the Milky Way, located in a dwarf galaxy called the Small Magellanic Cloud.
NASA/ESA
Two galaxies, known as II ZW96, form a swirl shape while merging in the constellation Delphinus.
NASA/ESA/CSA/STScI
The James Webb Space Telescope revealed features of a new protostar forming.
NASA/ESA/CSA/STScI
The James Webb Space Telescope captured a new perspective of the Pillars of Creation in mid-infrared light. The dust of this star-forming region, rather than the stars themselves, is the highlight, and resembles ghostly figures.
NASA/ESA/CSA/STScI
Webb captured a highly detailed snapshot of the so-called Pillars of Creation, a vista of three looming towers made of interstellar dust and gas that's speckled with newly formed stars. The area, which lies within the Eagle Nebula about 6,500 light-years from Earth, had previously been captured by the Hubble Telescope in 1995, creating an image deemed "iconic" by space observers.
NASA/ESA/CSA/STScI/JPL-Caltech
The two stars in WR140 produce shells of dust every eight years that look like rings, as captured by the Webb telescope.
NASA/ESA/CSA/ASU/UA/UM/JWST PEARLs Team
The James Webb Space Telescope and Hubble Space Telescope contributed to this image of galactic pair VV 191. Webb observed the brighter elliptical galaxy (left) and spiral galaxy (right) in near-infrared light, and Hubble collected data in visible and ultraviolet light.
ESA/NASA/CSA/J. Lee
The James Webb Space Telescope captured spiral galaxy IC 5332, which is over 29 million light-years away. The observatory's MIRI instrument peered through interstellar dust to see the galaxy's "bones."
NASA/ESA/CSA/STScI
Webb captured the clearest view of the Neptune's rings in over 30 years.
NASA/ESA/CSA/PDRS4all
The inner region of the Orion Nebula as seen by the telescope's NIRCam instrument. The image reveals intricate details about how stars and planetary systems are formed.
NASA/ESA/CSA/STScI/Webb ERO Production Team
NASA released a mosaic image of the Tarantula Nebula on Tuesday, September 6. The image, which spans 340 light-years, shows tens of thousands of young stars that were previously obscured by cosmic dust.
NASA/ESA
A new image of the Phantom Galaxy, which is 32 million light-years away from Earth, combines data from the James Webb Space Telescope and the Hubble Space Telescope.
NASA/ESA/CSA/Jupiter ERS Team
NASA released an image of Jupiter on Monday, August 22, that shows the planet's famous Great Red Spot appearing white.
NASA/ESA/CSA/STScI
The James Webb Space Telescope captured the Cartwheel galaxy, which is around 500 million light-years away, in a photo released by NASA on August 2.
NASA/ESA/CSA/STScI
Webb's landscape-like view, called "Cosmic Cliffs," is actually the edge of a nearby, young, star-forming region called NGC 3324 in the Carina Nebula. The telescope's infrared view reveals previously invisible areas of star birth.
NASA/ESA/CSA/STScI
The five galaxies of Stephan's Quintet can be seen here in a new light. The galaxies appear to dance with one another, showcasing how these interactions can drive galactic evolution.
NASA/ESA/CSA/STScI
This side-by-side comparison shows observations of the Southern Ring Nebula in near-infrared light, left, and mid-infrared light, right, from NASA's Webb telescope. The Southern Ring Nebula is 2,000 light-years away from Earth. This large planetary nebula includes an expanding cloud of gas around a dying star, as well as a secondary star earlier on in its evolution.
NASA/ESA/CSA/STScI
President Joe Biden released one of Webb's first images on July 11, and it's "the deepest and sharpest infrared image of the distant universe to date," according to NASA. The image shows SMACS 0723, where a massive group of galaxy clusters act as a magnifying glass for the objects behind them. Called gravitational lensing, this created Webb's first deep field view of incredibly old and distant, faint galaxies.

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New images from the James Webb Space Telescope have revealed surprising pairs of planet-like objects in the Orion Nebula that have never been detected before.

The Orion Nebula, a glowing cloud of dust and gas, is one of the brightest nebulae in the night sky and identifiable as the sword in the Orion constellation. Located 1,300 light-years from Earth, the nebula has long presented astronomers with a wealth of celestial objects to study, including planet-forming disks around young stars and brown dwarfs, or objects with a mass between that of planets and stars.

Astronomers used Webb’s near-infrared camera, called NIRCam, to capture mosaics of the Orion Nebula in short and long wavelengths of light, revealing unprecedented details and unexpected discoveries.

When astronomers Samuel G. Pearson and Mark J. McCaughrean studied the short-wavelength image of the Orion Nebula, they zoomed in on the Trapezium Cluster, a young star-forming region that’s about 1 million years old, filled to the brim with thousands of new stars. In addition to the stars, the scientists spotted brown dwarfs, which are too small to kick-start the nuclear fusion at their cores to become stars. Brown dwarfs have a mass that is below 7% the mass of the sun.

On the hunt for other low-mass isolated objects, the astronomers found something they had never seen: pairs of planet-like objects with masses between 0.6 and 13 times the mass of Jupiter that appear to defy some fundamental astronomical theories.


The scientists dubbed them Jupiter Mass Binary Objects, or JuMBOs.

“Although some of them are more massive than the planet Jupiter, they will be roughly the same size and only slightly larger,” said Pearson, a European Space Agency research fellow at the European Space Research and Technology Centre in the Netherlands.

The astronomers found 40 pairs of JuMBOs and two triple systems, all on wide orbits around one another. Although they exist in pairs, the objects are typically about 200 astronomical units apart, or 200 times the distance between Earth and the sun. It can take between 20,000 and 80,000 years for the objects to complete an orbit around each other.

ESA
Five JuMBOs can be seen in this image, which zoomed in on the finer details of the larger Webb portrait of the Trapezium Cluster in the Orion Nebula.

The objects’ temperatures range from 1,000 degrees Fahrenheit (537 degrees Celsius) to 2,300 F (1,260 C), Pearson said. The gaseous objects are young, astronomically speaking — about 1 million years old. Our solar system, in comparison, is 4.57 billion years old.

“We are halfway through the life of the sun, so these objects in Orion are 3-day-old babies,” said McCaughrean, senior adviser for science and exploration at the European Space Agency. “They’re still quite luminous and warm because the energy they have when they get created still allows them to glow, which is how we can see these things in the first place.”

McCaughrean and Pearson have written two research papers based on their discoveries in the Orion Nebula using the Webb telescope. The studies have been submitted to academic journals for publication, and the preliminary findings are available on a preprint site called arXiv. But many questions about JuMBOs remain — including how they came to be in the first place.

JuMBOs: Upending the rules of astronomy

Stars form from giant clouds of gas and dust that collapse beneath gravitational forces. This process continues as disks of gas and dust swirl around the stars, giving rise to planets. But no existing theories explain how the JuMBOs formed, or why they’re present in the Orion Nebula, McCaughrean said.

For instance, some may consider the JuMBOs to be like rogue planets, or objects of planetary mass that freely travel through space without orbiting stars. But many rogue planets begin by orbiting stars before being ejected, and it would be hard to explain how pairs of them were kicked out at the same time while remaining gravitationally connected to each other.

NASA/ESA/CSA
This Webb image shows the full survey of the inner Orion Nebula and Trapezium Cluster, captured in long wavelengths of light.

“Scientists have been working on theories and models of star and planet formation for decades, but none of them have ever predicted that we would find pairs of super low mass objects floating alone in space — and we’re seeing lots of them,” Pearson said. “The main thing that we learn from this is that there is something fundamentally wrong with either our understanding of planet formation, star formation, or both.”

The Orion Nebula is a favorite observational target of astronomers, and the larger and more sophisticated telescopes become, the more objects are revealed within the nebula, McCaughrean said.

“While the objects we are looking at are really faint, they are brightest in the infrared, so that (is) where you have the best chance of detecting them,” Pearson said via email. “JWST is the most powerful infrared telescope that has ever been built and these observations simply wouldn’t be possible with any other telescope.”

Observations of the nebula scheduled for early 2024 could provide more insight into the atmospheric compositions of the JuMBOs, Pearson said. The researchers also want to uncover more details about the objects, including making precise measurements of their masses.

Meanwhile, other research focused on different star-forming regions could reveal whether JuMBOs are elsewhere beyond the Orion Nebula.

“The main question is, ‘What?! Where did that come from?’” Pearson said. “It’s just so unexpected that a lot of future observations and modelling are going to be needed to explain it.”