Tag Archives: protoplanetary

Scientists Uncover Largest Protoplanetary Disk Ever Detected Around Young Star

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IRAS 23077+6707: A Turbulent Protoplanetary Disk – Located approximately 1,000 light-years away, this young star exhibits an unexpectedly chaotic and turbulent surrounding protoplanetary disk, with material fragments extending farther than what astronomers have previously observed in similar systems. For more details, check the study here.

This Hubble image showcases the protoplanetary disk surrounding IRAS 23077+6707. Image credit: NASA / ESA / STScI / K. Monsch, CfA / J. DePasquale, STScI.

Protoplanetary disks, rich in dust and gas, form around young stars and serve as primary locations for planet formation.

The disk surrounding IRAS 23077+6707 spans approximately 644 billion km (400 billion miles), making it about 40 times the diameter of our solar system, reaching to the outer Kuiper belt.

This vast disk obscures the star, which scientists suggest could be a massive star or potentially a binary star system.

Not only is this disk the largest known for planet formation, but its unique characteristics also make it exceptionally rare.

“It’s uncommon to capture such fine detail in protoplanetary disks. The new Hubble images suggest that planetary nurseries might be much more dynamic and chaotic than we previously thought,” explained Dr. Christina Monsch, an astronomer at Harvard University and the Smithsonian Center for Astrophysics.

“Observing this disk nearly head-on reveals its delicate upper layers and asymmetrical features,” she added.

Both the NASA/ESA Hubble Space Telescope and the NASA/ESA/CSA James Webb Space Telescope have glimpsed similar structures, but IRAS 23077+6707 allows for unmatched visibility of its substructure in visible light.

This unique perspective makes it an exceptional laboratory for studying planet formation and the environments in which it occurs.

Edge-on, these disks resemble hamburgers, with bright upper and lower layers of glowing dust and gas, separated by a dark central lane.

In addition to its significant height, the new images reveal that vertical filament-like structures only appear on one side of the disk, indicating an uneven distribution of material.

“We were astonished by how asymmetric this disk appeared,” noted Dr. Joshua Bennett Lovell from the Harvard University & Smithsonian Center for Astrophysics.

“Hubble provides us with an exceptional view of the chaotic processes involved in the formation of disks and new planets. This process remains poorly understood, but these insights allow for fresh study opportunities.”

All planetary systems originate from a disk of gas and dust surrounding young stars. Over time, gas is absorbed by the star while planets form from the remaining material.

IRAS 23077+6707 might act as an extended analog to the early Solar System, with an estimated disk mass between 10 to 30 times that of Jupiter, providing sufficient material for multiple gas giant planets.

This and other discoveries make IRAS 23077+6707 an extraordinary case for examining planetary system formation.

“Theoretically, IRAS 23077+6707 could support a vast planetary system,” Dr. Monch stated.

“While planet formation may differ in such expansive conditions, the fundamental processes are likely akin to those in smaller systems.”

“At this point, we have more questions than answers, but these new images serve as a valuable foundation for understanding how planets evolve in diverse environments.”

Findings are set to be published in the Astrophysical Journal and can be accessed here.

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Christina Monche et al. 2025. Hubble reveals the complex multiscale structure of the edge-on protoplanetary disk IRAS 23077+6707. APJ in press. arXiv: 2510.11819

Source: www.sci.news

Candidates Around Young Stars in VLT: Identification of Protoplanetary and Sub-Ceres Objects

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Using Enhanced Resolution Imagers and Spectrographs (ERIS) from ESO’s Very Large Telescope (VLT), two teams of astronomers have discovered a protoplanet candidate nestled within a spiral disk surrounding the young star HD 135344B.

This image depicts a spiral disk surrounding Young Star HD 135344b. The observations made using the Enhanced Resolution Imager and Spectrograph (ERIS) identified a candidate planet contributing to the spiral structure in the disk, marked by a white circle. Image credits: ESO/Maio et al.

“While we may never witness the formation of Earth, this is a significant finding,” says Francesco Maio, a doctoral researcher at the University of Florence in Italy and lead author of a paper published in the journal Astronomy and Astrophysics.

Maio and his colleagues identified protoplanet candidates in the surrounding protoplanetary disks of HD 135344b. This F8V star, approximately 11.9 million years old, is situated 135 parsecs (440 light-years) from the Sun, in the Lupus constellation.

The protoplanet is estimated to be twice the size of Jupiter, located at a distance from its host star comparable to that of Neptune from the Sun.

It has been observed maturing at the periphery of the protoplanetary disk as it evolves into a fully-fledged planet.

Similar protoplanets have been detected around other young stars, often exhibiting intricate features such as rings, gaps, and spirals.

Astronomers long suspected that these structures were sculpted by forming planets, clearing away material as they orbit their parent stars.

Until now, however, no one has identified a planet actively shaping these features.

In the discs of HD 135344B, previous observations of swirling spiral arms were made by another team using VLT’s Sphere instrument.

Yet prior observations did not find evidence of any planets forming within this disk.

Utilizing VLT’s ERIS instrument, Maio and his collaborators may have discovered their primary suspect.

They identified a planetary candidate located at the base of one of the spiral arms of the disk, aligning with theoretical predictions about potential planets responsible for such patterns.

“What marks this detection as potentially groundbreaking is our ability to directly observe the signal from the protoplanet, unlike many earlier observations,” he notes.

“This gives us greater confidence in the existence of this planet, as we can see the light it emits.”

This image illustrates possible sub-brown dwarf companions orbiting Young Star V960 Mon. Candidate objects were detected using ESO’s Very Large Telescope (VLT) and the new Enhanced Resolution Imager and Spectrograph (ERIS). The ERIS data is shown in orange, overlaid with prior dusty disk images from VLT’s Sphere instruments (yellow) and ALMA (blue). Image credits: ESO/A. Dasgupta/ALMA/ESO/NAOJ/NRAO/Weber et al.

In a separate study, Anuroop Dasgupta, a doctoral researcher at ESO and Diego Portales University, along with colleagues, observed another young star using the ERIS instrument. V960 is located 1637.7 parsecs (5,342 light-years) away in the Monoceros constellation.

Prior observations using Sphere equipment and large millimeter/sub-millimeter arrays (ALMA) revealed that the material orbiting V960 Mon is shaped into complex spiral arms.

These observations also indicated that large clumps of material around the star undergo gravitational instability, contracting and collapsing—each capable of forming a planet or larger body, thus fragmenting the material.

Dasgupta and his collaborators managed to identify a brown dwarf or sub-brown dwarf companion around V960 Mon.

“Using ERIS, we aimed to discover compact, bright fragments indicative of companions in the disk,” he explains. Their findings are detailed in a paper published in the Astrophysical Journal Letters.

“One potential companion object was found very close to one of the observed spiral arms in the Universe and in ALMA data.”

“This object could represent a planet or a brown dwarf—larger than a planet but lacking sufficient mass to shine like a star.”

“If confirmed, this companion could be the first clear identification of a planet or brown dwarf formed via gravitational instability.”

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F. Maio et al. 2025. Development of Protoplanet candidates embedded using VLT/ERIS on HD135344B disks. A&A 699, L10; doi:10.1051/0004-6361/202554472

Anuroop Dasgupta et al. 2025. VLT/ERIS observations for the V960 series: dust-embedded sub-brown dwarf objects formed by gravitational instability? ApJL 988, L30; doi: 10.3847/2041-8213/ade996

Source: www.sci.news

Protoplanetary disks surrounding stars similar to the Sun seem to have had a longer lifespan in the early universe

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In 2003, Hubble provided evidence of giant exoplanets around very old stars. Such stars have only small amounts of the heavy elements that make up planets. This suggests that some planetary formation occurred when our universe was very young, and that those planets had time to form and grow large within the primordial disk, becoming even larger than Jupiter. I am. But how? To answer this question, astronomers used the NASA/ESA/CSA James Webb Space Telescope to study stars in the nearby Small Magellanic Cloud, which, like the early Universe, lacks large amounts of heavy elements. They discovered that not only do some stars there have planet-forming disks, but that those disks are longer-lived than the disks found around young stars in our Milky Way galaxy.

This web image shows NGC 346, a massive star cluster in the Small Magellanic Cloud. Yellow circles superimposed on the image indicate the positions of the 10 stars investigated in the study. Image credits: NASA/ESA/CSA/STScI/Olivia C. Jones, UK ATC/Guido De Marchi, ESTEC/Margaret Meixner, USRA.

“With Webb, we have strong confirmation of what we saw with Hubble, and we need to rethink how we model planet formation and early evolution in the young Universe.” European Space Research Agency said Dr. Guido de Marchi, a researcher at Technology Center.

“In the early universe, stars formed primarily from hydrogen and helium, with few heavier elements such as carbon or iron, and were later born from supernova explosions.”

“Current models predict that because heavy elements are so scarce, the lifetime of the disk around the star is short, so short that in fact planets cannot grow,” said a researcher at NSF's NOIRLab's Gemini Observatory. said lead scientist Dr. Elena Sabbi.

“But Hubble actually observed those planets. So what happens if the model is incorrect and the disks have a longer lifespan?”

To test this idea, the astronomers trained Webb in the Small Magellanic Cloud, a dwarf galaxy that is one of the closest galaxies to the Milky Way.

In particular, they examined the massive star-forming cluster NGC 346, which also has a relative lack of heavy elements.

This cluster served as a nearby proxy for studying stellar environments with similar conditions in the distant early universe.

Hubble observations of NGC 346 since the mid-2000s have revealed that there are many stars around 20 to 30 million years old that are thought to still have planet-forming disks around them.

This was contrary to the conventional idea that such disks would disappear after two or three million years.

“Hubble's discovery was controversial and went against not only the empirical evidence for the galaxy, but also current models,” Dr. De Marchi said.

“This was interesting, but without a way to obtain the spectra of these stars, we will not know whether what we are witnessing is genuine accretion and the presence of a disk, or just an artificial effect. I couldn't actually confirm it.”

Now, thanks to Webb's sensitivity and resolution, scientists have, for the first time, spectra of the formation of Sun-like stars and their surrounding environments in nearby galaxies.

“We can see that these stars are actually surrounded by a disk and are still in the process of engulfing material even though they are relatively old, 20 or 30 million years old,” De Marchi said. Ta.

“This also means that planets have more time to form and grow around these stars than in nearby star-forming regions in our galaxy.”

This discovery contradicts previous theoretical predictions that if there were very few heavy elements in the gas around the disk, the star would quickly blow away the disk.

Therefore, the lifespan of the disk is very short, probably less than 1 million years.

But how can planets form if dust grains stick together to form pebbles and the disk doesn't stay around the star long enough to become the planet's core?

The researchers explained that two different mechanisms, or a combination of them, may exist for planet-forming disks to persist in environments low in heavy elements.

First, the star applies radiation pressure to blow the disk away.

For this pressure to be effective, an element heavier than hydrogen or helium must be present in the gas.

However, the massive star cluster NGC 346 contains only about 10 percent of the heavy elements present in the Sun's chemical composition.

Perhaps the stars in this cluster just need time to disperse their disks.

A second possibility is that for a Sun-like star to form when there are few heavier elements, it would need to start with a larger cloud of gas.

As the gas cloud grows larger, it produces larger disks. Therefore, because there is more mass in the disk, it will take longer to blow it away, even if the radiation pressure is acting the same.

“The more material around the star, the longer the accretion will last,” Sabbi says.

“It takes 10 times longer for the disk to disappear. This has implications for how planets form and the types of system architectures that can be used in different environments. This is very exciting.”

of study Published today on astrophysical journal.

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Guido de Marchi others. 2024. Protoplanetary disks around Sun-like stars appear to live longer when they are less metallic. APJ 977,214;Doi: 10.3847/1538-4357/ad7a63

This article is adapted from an original release by the Webb Mission Team at NASA's Goddard Space Flight Center.

Source: www.sci.news

Astronomers Propose that X-ray and Ultraviolet Radiation Impact the Protoplanetary Disk in Cygnus OB2

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Cygnus OB2 is the giant young stellar association closest to the Sun.

In this new composite image, Chandra data (purple) shows the diffuse X-ray emission and young stars of Cygnus OB2, along with infrared data (red, green, blue, cyan) from NASA's now-retired Spitzer Space Telescope reveals young stars. And it creates cold dust and gas throughout the region. Image credits: NASA / CXC / SAO / Drake others. / JPL-California Institute of Technology / Spitzer / N. Walk.

At a distance of approximately 1,400 parsecs (4,600 light years), Cygnus OB2 It is a huge young body closest to the Sun.

It contains hundreds of double stars and thousands of low-mass stars.

Dr. Mario Giuseppe Guarcero of the National Institute of Astrophysics, Dr. Juan Facundo Albacete Colombo of the University of Rio Negro, and colleagues used NASA's Chandra X-ray Observatory to study various regions of Cygnus OB2. observed.

This deep observation mapped the diffuse X-ray glow between the stars and also provided an inventory of young stars within the cluster.

This inventory was combined with other inventories using optical and infrared data to create the best survey of young stars within the association.

“These dense stellar environments are home to large amounts of high-energy radiation produced by stars and planets,” the astronomers said.

“X-rays and intense ultraviolet radiation can have devastating effects on planetary disks and systems that are in the process of forming.”

The protoplanetary disk around the star naturally disappears over time. Part of the disk falls onto the star, and some is heated by X-rays and ultraviolet light from the star and evaporates in the wind.

The latter process, known as photoevaporation, typically takes 5 million to 10 million years for an average-sized star to destroy its disk.

This process could be accelerated if there is a nearby massive star that produces the most X-rays and ultraviolet light.

researchers Found Clear evidence that protoplanetary disks around stars actually die out much faster when they approach massive stars that produce large amounts of high-energy radiation.

Also, in regions where stars are more densely packed, the disk dies out faster.

In the region of Cygnus OB2, which has less high-energy radiation and fewer stars, the proportion of young stars with disks is about 40%.

In regions with higher-energy radiation and more stars, the proportion is about 18%.

The strongest influence, and therefore the worst location for a star to become a potential planetary system, is within about 1.6 light-years of the most massive star in the cluster.

In another study, the same team I looked into it Characteristics of the diffuse X-ray emission of Cygnus OB2.

They discovered that the high-energy, diffuse radiation originates from regions where winds of gas blown from massive stars collide with each other.

“This causes the gas to become hot and generate X-rays,” the researchers said.

“The low-energy release is likely caused by gas within the cluster colliding with gas surrounding the cluster.”

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MG Guarcero others. 2024. Photoevaporation and close encounters: How does the environment around Cygnus OB2 affect the evolution of the protoplanetary disk? APJS 269, 13; doi: 10.3847/1538-4365/acdd67

JF Albacete vs Colombo others. 2024. Diffuse X-ray emission in the Cygnus OB2 coalition. APJS 269, 14;doi: 10.3847/1538-4365/acdd65

Source: www.sci.news

Webb uncovers high levels of hydrocarbons in protoplanetary disks surrounding ultra-low-mass stars

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Very low-mass stars orbit rocky exoplanets more frequently than other types of stars. The composition of these planets is poorly understood, but it is thought to be related to the protoplanetary disk in which they form. In the new study, astronomers used the NASA/ESA/CSA James Webb Space Telescope to investigate the chemical composition of the planet-forming disk around ISO-ChaI 147, a red dwarf star just one-tenth the mass of the Sun. They identified emission from 13 carbon-containing molecules, including ethane and benzene.

This is an artist's impression of a young star surrounded by a disk of gas and dust. Image courtesy of NASA/JPL.

ISO-ChaI 147 It is a red dwarf star with a mass 0.11 times that of the Sun, located about 639 light years away in the constellation Chamaeleon.

The star was observed as part of the MIRI Mid-Infrared Disk Survey (MINDS), which aims to bridge the gap between the chemical composition of the disk and the properties of exoplanets.

These observations provide insight into the environments and fundamental elements for the formation of such planets.

Astronomers discovered that the gas in ISO-ChaI 147's planet-forming region is rich in carbon.

This could be due to carbon being removed from the solid material from which rocky planets form, which could explain why Earth is relatively carbon-poor.

“WEBB has greater sensitivity and spectral resolution than conventional infrared space telescopes,” said Dr Aditya Arabavi, an astronomer at the University of Groningen.

“These observations are not possible from Earth because the radiation is blocked by the atmosphere.”

“So far we have only been able to identify acetylene emissions from this object.”

“But Webb's high sensitivity and spectral resolution allowed us to detect faint emissions from fewer molecules.”

“Thanks to Webb, we now know that these hydrocarbon molecules are not only diverse, but abundant as well.”

The spectrum of ISO-ChaI 147 shows the richest hydrocarbon chemical composition ever observed in a protoplanetary disk, consisting of 13 carbon-containing molecules. Image credit: NASA/ESA/CSA/Ralf Crawford, STScI.

The spectrum of ISO-ChaI 147 is Webb's mid-infrared measuring instrument (MIRI) displays the richest hydrocarbon chemical composition ever observed in a protoplanetary disk, consisting of 13 carbon-containing molecules up to benzene.

This includes the first extrasolar detection of ethane, the largest fully saturated hydrocarbon detected outside the solar system.

Fully saturated hydrocarbons are expected to form from more basic molecules, so detecting them here can give researchers clues about their chemical environment.

Astronomers also detected ethylene, propyne, and methyl radicals in a protoplanetary disk for the first time.

“These molecules have already been detected in our solar system, for example in comets such as 67P/Churyumov-Gerasimenko and C/2014 Q2 (Lovejoy),” Dr. Arababi said.

“It's amazing that we can now see these molecules dancing in the cradle of the planet.”

“This is a completely different environment to how we normally think of planet formation.”

The team note that these results have significant implications for the astrochemistry within 0.1 AU and the planets that form there.

“This is very different to the composition found in disks around solar-type stars, where oxygen-containing molecules (such as carbon dioxide and water) dominate,” said Dr Inga Kamp, also from the University of Groningen.

“This object proves that these are unique classes of objects.”

“It's incredible that we can detect and quantify the amount of a molecule that's well known on Earth, such as benzene, in an object more than 600 light years away,” said Dr Agnes Perrin, an astronomer at the French National Center for Scientific Research.

Team result Published in today's journal Science.

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AM Arabavi other2024. Abundant hydrocarbons present in a disk around a very low-mass star. Science 384, 6700: 1086-1090; doi: 10.1126/science.adi8147

Source: www.sci.news

MUSE finds peculiar star surrounded by a luminous protoplanetary disk

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Astronomers Multi-unit spectroscopic probe The (MUSE) instrument on ESO’s Very Large Telescope (VLT) in Chile has imaged Propride, an externally illuminated protoplanetary disk around a young star, at 177-341 W. Orion Nebula.

This VLT/MUSE image shows propylid 177-341 W. Image courtesy of ESO / Aru others., doi: 10.1051/0004-6361/202349004.

Young stars are surrounded by a disk of gas and dust that gives rise to planets.

If another very bright and massive star is nearby, its light can heat up the young star’s disk and strip it of some of its material.

“Protoplanetary disks made of gas and dust emerge as a result of star formation processes and are the birth sites for planetary systems,” explained ESO astronomer Marie-Rees-Al and her colleagues.

“The evolutionary path of a protoplanetary disk and its ability to form planets depend on the surrounding environment, and we expect disks to undergo rapid changes in the presence of massive stars.”

“In massive clusters close to OB stars, ultraviolet (UV) radiation can cause the disk to photoevaporate externally, significantly reducing its size, mass, and lifetime.”

Astronomers used the MUSE instrument on ESO’s Very Large Telescope to observe 177-341W and 11 other dwarf stars in the Orion Nebula Cluster, about 400 parsecs away from the Sun.

“The stars encroaching on 177-341 W’s disk drop out of the frame after passing the upper right corner,” the researchers said.

“When that radiation collides with the material around the young star, it creates the bright bow-like structures we see in yellow.”

“The tail extending from the star toward the lower left corner is material being dragged away from 177-341 W by a star outside the field of view.”

“The colours displayed in this image represent different elements, including hydrogen, nitrogen, sulphur and oxygen,” the researchers added.

“But this is only a small part of the total data collected by MUSE. MUSE actually takes thousands of images simultaneously in different colors and wavelengths.”

a paper The findings have been published in the journal Astronomy and Astrophysics.

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M.-L. Al others2024. A kaleidoscope of irradiated disks: Propride MUSE observations of the Orion Nebula Cluster. I. Sample presentation and size of the ionization front. A&Ain press; doi: 10.1051/0004-6361/202349004

Source: www.sci.news

86 young stars found to have protoplanetary disks by VLT

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New observations of 86 planet-forming disks provide astronomers with a wealth of data and unique insight into how planets form in different regions of the Milky Way.

A planet-forming disk around a young star and its location in the gas-rich clouds of the constellation Taurus, about 600 light-years from Earth. Scientists observed a total of 43 stars in the Taurus region, all of which are pictured here (although planet-forming disks were detected in only 39 of these targets) ).Image credit: ESO / Galfi other. /Iras.

More than 5,000 exoplanets have been discovered to date, many of them in planetary systems significantly different from our solar system.

To understand where and how this diversity occurs, astronomers need to look at the dust- and gas-rich disks that envelop young stars: the cradles of planet formation. These are most commonly found in the giant gas clouds in which the stars themselves are forming.

As with mature planetary systems, new images from ESO's Very Large Telescope (VLT) show the amazing diversity of planet-forming disks.

“Some of these disks show huge spiral arms, probably driven by a complex ballet of orbiting planets,” said Christian Ginski, an astronomer at the University of Galway.

“Some show rings or large cavities formed by planet formation, while others appear smooth and almost dormant amidst this hustle and bustle of activity,” said Antonio Galfi, an astronomer at the Arcetri Astrophysical Observatory. he added.

The authors studied a total of 86 stars across three different star-forming regions in the Milky Way. Taurus and Chameleon I are both about 600 light-years from Earth, and Orion is a gas-rich cloud about 1,600 light-years from us. It is known as the birthplace of several stars more massive than the Sun.

In the Orion cloud, we found that stars in groups of two or more are less likely to have large disks that form planets.

This is an important result given that, unlike our Sun, most stars in our galaxy have companion stars.

In addition to this, the uneven appearance of the disk in this region suggests that there may be a giant planet embedded within it, which could cause the disk to become distorted or misaligned. there is.

Planet-forming disks can extend to distances hundreds of times the distance between Earth and the Sun, but because of their location hundreds of light-years from us, they appear like tiny needles in the night sky. I can see it.

To observe the protoplanetary disk, astronomers used the VLT's Spectropolarimetric High-Contrast Exoplanet Research Equipment (SPHERE).

Additional data was obtained using VLT's X-SHOOTER instrument, allowing researchers to determine how young the star is and how massive it is.

The Atacama Large Millimeter/Submillimeter Array (ALMA) has helped us understand more about the amount of dust around some stars.

Per Gunnar Vallegord, a PhD student at the University of Amsterdam, said: “The process that marks the beginning of the journey towards the formation of planets and, ultimately, the formation of life in our solar system could not be more beautiful. It's almost poetic that it is.”

The results of this study will be published in three papers. journal astronomy and astrophysics.

Source: www.sci.news

ALMA observes water vapor in young star’s protoplanetary disk

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Water molecules are key components in the formation of planetary systems. Astronomers using the Atacama Large Millimeter/Submillimeter Array (ALMA) have detected water vapor in the disk around the young star HL Taurus, where planets may be forming. Their analysis suggests that the hard lower limit for water vapor availability within the interior 17 astronomical units of the Taurus HL system is 3.7 Earth Oceans.

This ALMA image shows water vapor (blue tints) in the protoplanetary disk around HL Taurus. Near the center of the disk, where young stars live, the environment is hotter and the gas brighter. The red ring is a previous ALMA observation showing the distribution of dust around the star.Image credits: ALMA / ESO / National Astronomical Observatory of Japan / NRAO / Facchini other.

Water molecules are undoubtedly one of the most important molecular species in the entire universe.

Water is a highly efficient solvent, so it played a key role in the emergence of life as we know it on Earth.

For this reason, chemical characterization of exoplanetary atmospheres often focuses on detecting this specific molecule.

Water, formed from common hydrogen and oxygen atoms, is so abundant in both gas and ice form that it plays a fundamental role in the physics of planetary system formation.

Dr Stefano Facchini, an astronomer at the University of Milan, said: “We never imagined that we would be able to image oceans of water vapor in areas where planets are likely to form.”

The HL Taurus system is believed to be less than 100,000 years old and has a radius of about 17.9 billion km. It is located 450 light years away in the direction of the constellation Taurus.

The protoplanetary disk of HL Taurus is unusually large and bright, making it a perfect place to look for signs of planet formation.

New ALMA observations reveal that there is at least three times more water inside the disk than in Earth's entire ocean.

Dr Leonardo Testi, an astronomer at the University of Bologna, said: “It is truly amazing that we can not only detect water vapor 450 light-years from us, but also obtain detailed images and spatially resolve it.” said.

Spatially resolved observations with ALMA allow astronomers to determine the distribution of water in different regions of the disk.

“Participating in such an important discovery of the iconic HL Taurus disk was beyond my expectations given my first research experience in astronomy,'' said Dr. Mathieu Vander Donk, an astronomer at the University of Liege. he said.

Dr Facchini said: “Our recent images reveal that significant amounts of water vapor are present at distances from the star that include gaps where planets may now be forming.” said.

“This suggests that this water vapor could influence the chemical composition of planets that form in those regions.”

“To date, ALMA is the only facility capable of spatially resolving water in cold planet-forming disks,” said Professor Wouter Bremings, an astronomer at Chalmers University of Technology.

ESO astronomer Dr Elizabeth Humphreys said: “It's really exciting to be able to witness first-hand in photographs the ejection of water molecules from icy dust particles.”

“The dust particles that make up the disk are the seeds for planet formation, colliding and clumping together to form even larger bodies orbiting the star.”

“Our findings show how the presence of water influences the development of planetary systems, similar to our own solar system about 4.5 billion years ago,” Dr. Facchini said.

of findings It was published in the magazine natural astronomy.

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S. Facchini other. HL Resolved ALMA observations of water in the inner astronomical unit of the Tau disk. Nat Astron, published online on February 29, 2024. doi: 10.1038/s41550-024-02207-w

Source: www.sci.news