Tag Archives: Radcliffe

Astronomers Report Our Solar System Surpassed the “Radcliffe Waves” in the Miocene Era

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As our solar system orbits the Milky Way, we encounter a variety of environments, including dense regions of interstellar media. These encounters can increase the flow of interstellar dust into the solar system and the Earth's atmosphere, exposing parts of the solar system to interstellar mediums. The discovery of new galactic structures, such as the Radcliffe waves over the 9,000 Wright years, raises the question of whether the Sun encountered any of them. New research shows that the solar system trajectories intersected with the waves of Radcliffe in the Orion star-forming region 15 to 12 million years ago (Miocene era). In particular, this period coincides with the mid-Miocene climate transition on Earth, providing an interdisciplinary connection with paleoclimatology.

Radcliffe wave visualization. Image credit: Alyssa Goodman/Harvard University.

When the solar system brings the Milky Way into orbit, we encounter a variety of galactic environments with different interstellar densities, including hot voids, fronts of supernova blasts, and cold gas clouds.

The passage of the sun through dense regions of interstellar media can affect the solar system in several ways.

For example, pressure enhancement compresses the heliosphere and exposes parts of the solar system to cold, dense interstellar media.

Furthermore, the amount of interstellar dust mounted on the Earth's atmosphere can increase, potentially enhancing the delivery of radioactive isotopes such as iron-60 through dust grains.

Radcliffe's waves are narrow sinusoidal gas structures and consist of many known star-forming cloud complexes, including CMA, Orion, Taurus, Perseus, Cephaus, North American Nebula, and Cygnus.

With an estimated mass of 3 million people, this gas structure appears to vibrate consistently like a moving wave and is thought to be part of the Milky Way spiral structure.

Dr. Efrem Macconi, a doctoral student at the University of Vienna, said:

“Our Sun encountered a higher gas density region as it passed through the waves of Radcliffe in the Orion constellation.”

Using data from ESA's Gaia mission and spectroscopic observations, Dr. Maconi and his colleagues identified the passage of the solar system through the Radcliffe Wave in the Orion area.

“The findings are based on previous works identifying Radcliffe's waves,” said Professor Joanne Albes of the University of Vienna.

“We passed the Orion area as well as famous star clusters like NGC 1977, NGC 1980 and NGC 1981.”

“The area is easily visible in the winter sky in the Northern Hemisphere and in the summer in the Southern Hemisphere.”

“Look for Orion Constellation and Orion Nebula (Messier 42) – our solar system has come from that direction!”

“The increased dust from this galaxy encounter may have had some effects.”

“It could potentially leave traces of radioactive elements from supernovas in the geological record that permeate the Earth's atmosphere.”

“Current technologies may not be sensitive enough to detect these traces, but future detectors may make it possible.”

This study shows that the solar system passing through the Orion region occurred around 18.2 to 11.5 million years ago, with the most likely time between 148 and 12.4 million years ago.

This time frame is in good agreement with the mid-Miocene climate transition, and is a major shift from warm variable climate to cool climates, leading to the establishment of a continental-scale prototype Antarctic ice sheet composition.

This study raises the possibility of a link between past crossings of the solar system through galaxy neighbours and Earth's climate through interstellar dust, but the authors need further investigation of the causal relationship. It emphasizes that there is.

“The basic processes responsible for the mid-Miocene climate transition have not been fully identified, but available reconstructions are most likely to be long-term reductions in atmospheric greenhouse gas carbon dioxide concentrations. It suggests that it is a high explanation.

“However, our research highlights that interstellar dust associated with the crossing of Radcliffe's waves has affected the Earth's climate and may have played a potential role during this climate change. Masu.”

“To change the Earth's climate, the amount of extraterrestrial dust on Earth needs to be much larger than what previous data suggests.”

“Future research explores the importance of this contribution. This past climate change and current climate change is comparable as this past climate change is unfolding over a timescale of hundreds of thousands of years. It is important to note that we do not do that.”

“In contrast, the evolution of global warming today has been happening at an unprecedented rate for decades to centuries due to human activity.”

study Published in the journal Astronomy and Astrophysics.

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E. Machoni et al. 2025. Passing through the solar system through the waves of Radcliffe in the mid-Miocene. A&A 694, A167; doi: 10.1051/0004-6361/202452061

Source: www.sci.news

Radcliffe waves found to exhibit oscillations by astronomers

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Our Sun is within 300 parsecs (about 1,000 light-years) of a 2,700-parsec (about 9,000 light-years) long sinusoidal dense gas cloud known as the Radcliffe wave. The wavy shape of this structure was discovered using 3D dust mapping, but initial kinematic investigations of its oscillatory motion were inconclusive. Radcliffe waves oscillate in the plane of the Milky Way galaxy, radiating away from the galaxy's center, according to a new study.

Radcliffe waves next to the sun (yellow dot) in a cartoon model of the Milky Way. The blue dots are a group of baby stars.The white line is the theoretical model by Konietzka other. It describes the current shape and movement of the wave. The magenta and green lines show how the waves will move in the future. Image credit: Ralf Konietzka / Alyssa Goodman / Worldwide Telescope.

“By using the movement of baby stars born in gas clouds along Radcliffe waves, we can track the movement of the natal gas and show that the Radcliffe waves are actually rippling,” says Ralph.・Dr. Konietzka said. He is a student at Harvard University and the Smithsonian Center for Astrophysics.

In 2018, astronomers mapped the 3D location of a stellar nursery in the sun's galactic neighborhood.

By combining new data, ESA's Gaia Mission Using a data-intensive “3D dust mapping” technique, they noticed an emerging pattern, leading to the discovery of the 2020 Radcliffe wave.

“This is the largest coherent structure that we know of, and it's in our immediate vicinity,” said Dr. Katherine Zucker, an astronomer at the Harvard University & Smithsonian Center for Astrophysics.

“It's been there all along. We just didn't know it because we weren't able to build high-resolution models in 3D to show the distribution of gas clouds near the Sun.”

Although the 3D dust map clearly showed that Radcliffe waves were present, sufficient measurements were not available at the time to confirm whether the waves were moving.

But in 2022, astronomers used a new release of Gaia data to assign 3D motion to young star clusters in Radcliffe waves.

By understanding the location and movement of the clusters, they were able to confirm that the entire Radcliffe wave was indeed undulating, moving like what physicists call a “traveling wave.”

“Traveling waves are the same phenomenon you see in sports stadiums, where people take turns standing and sitting to do waves,” Konietzka said.

“Similarly, star clusters along Radcliffe waves move up and down, creating patterns that travel through the galaxy's backyard.”

“In the same way that fans in a stadium are pulled back into their seats by Earth's gravity, Radcliffe waves are oscillated by the Milky Way's gravity.”

No one yet knows what causes Radcliffe waves or why they behave the way they do.

“Now we can test all the different theories about why the waves formed in the first place,” Dr. Zucker said.

“Those theories range from the explosion of a giant star called a supernova to disturbances outside the galaxy, such as a dwarf satellite galaxy colliding with the Milky Way,” Konietzka added.

“It turns out we don't need significant dark matter to explain the motion we observe.”

“The gravity of ordinary matter is enough to move waves.”

Furthermore, the discovery of this oscillation has raised new questions about the predominance of these waves in both the Milky Way and other galaxies.

Radcliffe waves appear to form the backbone of the Milky Way's closest spiral arms, so the ripples in these waves may be due to the oscillations of galactic spiral arms in general, making galaxies even more dynamic than previously thought. It may suggest that you are doing something.

“The question is: What causes the displacement that causes the ripples that we see?” said Professor Alyssa Goodman, an astronomer at Harvard University and the Smithsonian Center for Astrophysics.

“And does it happen throughout the galaxy? In every galaxy? Does it happen sometimes? Does it happen all the time?

of result appear in the diary Nature.

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R. Konietzka other. Radcliffe waves are oscillating. Nature, published online on February 20, 2024. doi: 10.1038/s41586-024-07127-3

Source: www.sci.news