Tag Archives: Sunlike

Astronomers Observe Coronal Mass Ejection from Young Sun-Like Star

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On Earth, we may not often realize it, but the sun regularly ejects massive clumps of plasma into space known as coronal mass ejections (CMEs). Astronomers, utilizing the NASA/ESA Hubble Space Telescope along with ground-based telescopes in Japan and South Korea, have begun to detect signs of multi-temperature CMEs. EK Draconis, a young G-type main sequence star, is located 112 light-years away in the northern constellation Draco.

Artist’s depiction of the coronal mass ejection from EK Draconis. Image provided by: National Astronomical Observatory of Japan

“Researchers believe that CMEs may have significantly impacted the development of life on Earth, given that the Sun was quite active in its early days,” stated Kosuke Namegata, an astronomer at Kyoto University, along with his colleagues.

“Historically, studies have indicated that young stars similar to our Sun often produce intense flares that surpass the largest solar flares recorded in contemporary times.”

“The massive CMEs from the early Sun could have drastically influenced the primordial conditions on Earth, Mars, and Venus.”

“Nevertheless, the extent to which these youthful stellar explosions produce solar-like CMEs remains uncertain.”

“Recent years have seen the detection of cold plasma in CMEs via ground-based optical methods.”

“However, the high speeds and frequent occurrences of significant CMEs predicted in earlier studies have yet to be confirmed.”

In their investigation, the authors concentrated on EK Draconis, a youthful solar analog estimated to be between 50 million and 125 million years old.

Commonly referred to as EK Dra and HD 129333, the star shares effective temperature, radius, and mass characteristics that make it an excellent analog for the early Sun.

“Hubble captured far-ultraviolet emission lines sensitive to high-temperature plasma, while three ground-based telescopes simultaneously recorded hydrogen alpha lines tracking cooler gas,” the astronomers explained.

“These synergistic multi-wavelength spectroscopic observations enabled us to observe both the hot and cold components of the eruption instantaneously.”

This research presents the first evidence of a multitemperature CME originating from EK Draconis.

“Our findings indicate that high-temperature plasma at around 100,000 K was ejected at speeds ranging from 300 to 550 km/s, followed approximately 10 minutes later by a lower-temperature gas around 10,000 K ejected at a speed of 70 km/s,” the astronomers reported.

“The hotter plasma contained significantly more energy than the cooler plasma. This implies that frequent intense CMEs in the past may have sparked strong shocks and high-energy particles capable of eroding or chemically altering the early atmospheres of planets.”

“Theoretical and experimental research suggests that robust CMEs and high-energy particles could play a key role in generating biomolecules and greenhouse gases vital for the emergence and sustainability of life on early planets.”

“Consequently, this discovery carries substantial implications for understanding the habitability of planets and the conditions under which life may have arisen on Earth—and potentially elsewhere.”

The team’s study was published in the journal Nature Astronomy.

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Namekata K. et al. Signs of multi-temperature coronal mass ejections identified in a young solar analog. Nat Astron published online on October 27, 2025. doi: 10.1038/s41550-025-02691-8

Source: www.sci.news

Saturn-Sized Planets Can Orbit the Closest Sun-Like Star

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What might the artistic concept of a gas giant in orbit around Alpha Centauri A resemble?

ESA/Webb Copyright: NASA, ESA, CSA, STSCI, R.

A massive planet comparable to Saturn is potentially identified orbiting a sun-like star in our nearest stellar system, Alpha Centauri.

Located just four light-years from Earth, Alpha Centauri is the closest star system to us, comprising three stars: Alpha Centauri A, Alpha Centauri B, and the Red Dwarf Star Proxima Centauri. Scientists have long speculated that planets akin to those in our solar system could exist in such systems, and whether planets can reside at distances similar to our Sun’s “habitable zone” around binary stars has been a matter of intrigue. “These stars are very bright, relatively close, and move quickly across the sky,” mentions Charles Baichman from Caltech in a statement.

Recent observations gathered by the James Webb Space Telescope (JWST) mid-infrared instrument suggest that a gas giant possibly as substantial as Saturn is orbiting the sun-like star, Alpha Centauri A. This discovery has come as a surprise. “Webb was specifically designed to identify the most distant galaxies, not exoplanets,” remarked Beichman, underscoring that such an identification must be meticulously coordinated through numerous observations, evaluations, and computer simulations, which “can yield remarkable insights.”

While previous methodologies for detecting planets relied on indirect measurements, the JWST executed a “more ambitious” approach by actually gathering light from potential planets, according to Alan Boss of Carnegie Science in Washington, DC, who was not involved in this particular study. Nevertheless, visibility of the potential planets was lost in subsequent observations.

“We’re encountering a case of a disappearing planet!” exclaimed Aniket Sanghi, also at Caltech, in a statement. The research team ran simulations of millions of possible trajectories to solve this conundrum, determining that “in half of the possible simulated orbits, the planet would have been too close to the star, making it undetectable by Webb in both February and April 2025,” he said.

As a gas giant, this planet wouldn’t support life as we know it. However, if this finding is validated, it could significantly enhance our understanding of planet formation around stars. “The mere existence of two closely situated stars within a stellar system will challenge our comprehension of how planets form, survive, and evolve under such chaotic circumstances,” Sangi pointed out. “This is also crucial for Earth, as it is our closest neighbor, beside the giant planets in our solar system, with a temperature and age somewhat akin to Earth.”

This revelation has been documented in two accepted papers for publication in Astrophysics Letters.

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Source: www.newscientist.com

Webb Discovers Crystallized Water Ice in Debris Disks Surrounding Young Sun-Like Stars

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Water ice plays a crucial role in the formation of giant planets and can also be delivered by comets to fully developed rocky planets. Utilizing data from the Near-infrared spectrometer (NIRSPEC), which is part of the NASA/ESA/CSA James Webb Space Telescope, astronomers have identified crystallized ice on a dusty fragment disk surrounding HD 181327.

Artist impression of a debris disk around the sun-like star HD 181327. Image credits: NASA/ESA/CSA/STSCI/RALF CRAWFORD, STSCI.

HD 181327 is a young main sequence star located approximately 169 light years away in the constellation Pictor.

Also referred to as TYC 8765-638-1 and WISE J192258.97-543217.8, the star is about 23 million years old and roughly 30% larger than the Sun.

Astronomer Chen Zai and a team at Johns Hopkins University utilized Webb’s NIRSPEC instrument to study HD 181327.

“The HD 181327 system is highly dynamic,” Dr. Xie noted.

“There are ongoing collisions occurring within the debris disk.”

“When these icy bodies collide, they release tiny particles of dusty water ice, which are ideally sized for Webb to detect.”

Webb’s observations reveal a significant gap between the star and its surrounding debris disk, indicating a considerable area devoid of dust.

Moreover, the structure of the fragment disk is reminiscent of the Kuiper Belt within our Solar System, where we find dwarf planets, comets, and various icy and rocky bodies that may also collide.

Billions of years ago, the Kuiper Belt in our own Solar System could have resembled the HD 181327 debris disk.

“Webb clearly detected crystallized water ice not only present in the debris disk but also in places like Saturn’s rings and the icy bodies of the Kuiper Belt,” Dr. Xie stated.

The water ice is not uniformly distributed across the HD 181327 system.

The majority is found in the coldest and most distant regions from the star.

“The area beyond the debris disk contains over 20% water ice,” Dr. Xie explained.

Near the center of the debris disk, Webb detected approximately 8% water ice.

In this region, frozen water particles may form slightly faster than they are destroyed.

Closest to the star, Webb’s detection was minimal.

Ultraviolet radiation from the star can evaporate the nearby water ice deposits.

It is also possible that the interiors contain rocky bodies, referred to as planets, which are “confined” such that their frozen water remains undetectable by Webb.

“The presence of ice facilitates planetary formation,” said Dr. Xie.

“Icy materials can ultimately contribute to the delivery of resources to terrestrial planets that may form over hundreds of millions of years in such systems.”

Survey results were published in the May 14, 2025 issue of the journal Nature.

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C. Xie et al. 2025. Water ice on debris disks around HD181327. Nature 641, 608-611; doi:10.1038/s41586-025-08920-4

Source: www.sci.news

Research Indicates Sun-like Star-shaped Outer Solar System Approached Billions of Years Ago

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At least 140 million Sun-like stars in our Milky Way galaxy may have experienced similar stellar flybys, according to a new study by astrophysicists from the Jülich Research Centre and Leiden University.

Snapshot of a flyby of an ancient star. Blue-green particles indicate TNOs injected into the planetary region by the flyby. The perturbation star passed through the disk at perihelion distance 110 AU, on the right side of the picture. Image courtesy of Pfalzner others., doi: 10.1038/s41550-024-02349-x.

The planets in our solar system accumulated from a disk of dust and gas orbiting the young Sun.

Thus, the planets move in circular orbits close to a common plane.

About 3,000 small bodies have been observed orbiting the Sun beyond Neptune. Surprisingly, most of them move in eccentric or inclined orbits.

Therefore, some force must have lifted these trans-solar objects (TNOs) out of the disk in which they formed and significantly altered their orbits.

“When we think about the solar system, we usually think of it ending with Neptune, the outermost known planet,” said Dr Susanne Pfalzner, astrophysicist at the Jülich Research Centre and lead author of the paper.

“However, thousands of objects are known to travel beyond the orbit of Neptune.”

“It is even suspected that there are tens of thousands of objects over 100 kilometers in diameter.”

“Surprisingly, many of these TNOs travel on eccentric orbits that are inclined with respect to the common orbital plane of the planets in our solar system.”

In this study, Dr. Falzner and her colleagues compared the properties of observed TNOs with thousands of flyby simulations to determine specific properties of stellar flybys that could potentially reproduce all of the different TNO populations, their locations, and relative abundances.

They Found A flyby of a 0.8 solar mass star at a distance of 110 AU could explain the inclined and highly eccentric orbits of known TNOs.

“We can even infer the orbits of very distant objects, such as Sedna, a dwarf planet discovered in the outermost solar system in 2003,” Dr Pfalzner said.

“There are also objects moving in orbits that are almost perpendicular to the planet's orbit.”

“Such flybys could even explain the orbits of two objects moving in the opposite direction to the planet: 2008 KV42 and 2011 KT19.”

“The best match we found in our simulations for the outer solar system today is a star that is slightly lighter than our Sun, about 0.8 times its mass,” said Dr Amis Govind, also of the Jülich research centre.

“It traveled about 16.5 billion kilometers from the Sun, which is about 110 times the distance between Earth and the Sun and just under four times the distance to the outermost planet, Neptune.”

Astrophysicists were surprised Found The irregular moons orbiting the giant planets in the solar system in distant, inclined, and eccentric orbits are actually TNOs that were launched into the inner solar system by close passes of their stars.

“Some of these objects could have been captured as moons by giant planets,” said Dr Simon Portegies Zwart, an astrophysicist at Leiden University.

“This would explain why the outer planets in our solar system have two different types of moons.”

“In contrast to regular moons, which orbit their planets in circular orbits close to the planet, irregular moons orbit their planets at greater distances in inclined, elongated orbits.”

“Until now, there has been no explanation for this phenomenon.”

“The beauty of this model is its simplicity. With just one source, it answers several outstanding questions about our solar system,” Dr Pfalzner said.

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Susanne Falzner othersOrbits of flybys of stars that formed the outer solar system. Nat AstronPublished online September 4, 2024; doi: 10.1038/s41550-024-02349-x

Susanne Falzner others2024. A close flyby of a star could inject an irregular moon from outside the solar system. Apu JL 972, L21;doi:10.3847/2041-8213/ad63a6

Source: www.sci.news