Tag Archives: Rotating

The Destiny of Rotating Giant Stars – Sciworthy

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At its core, a star is formed when gravity gathers matter tightly enough to facilitate nuclear fusion in its center while also ensuring it doesn’t generate enough energy to disintegrate. The equilibrium between the gravitational forces pulling inward and the radiative forces pushing outward is referred to as: hydrostatic equilibrium. This balance constrains the size that stars can attain. This limit is known as the Eddington mass limit, which is believed to range between 150 and 300 solar masses.

When stars rotate, they have an enhanced ability to maintain their structure because a rotating body generates a force directed inward from its outer edges. This force is called centripetal force. As the star spins, it applies a centripetal force that acts alongside gravity, balancing the radiation pressure. Recently, a group of scientists investigated how the rotation of giant stars impacts their lifetimes throughout cosmic history. Massive stars contribute significantly to key cosmic phenomena, and understanding their end stages can shed light on the universe’s formation, including the creation of black holes and supernovae.

The researchers employed grid-based modeling software called the Geneva Stellar Evolution Code, also known as Genec. This tool helped simulate stellar behavior and long-term evolution based on initial characteristics. GENEC treats a star as a multi-layered system and tracks the movement of matter across these layers over time.

Two primary variables in their simulations were the star’s rotation status and its initial mass, which ranged from 9 to 500 solar masses. The researchers indicated that current science portrays very massive stars, those exceeding 100 solar masses, as inherently unstable and unpredictable. To clarify this, the team analyzed results for these colossal stars, utilizing 2 other models.

To understand how the fates of giant rotating stars have evolved, the researchers examined the ratio of stars containing elements heavier than hydrogen and helium ( metallic). They argued that since the early universe after the Big Bang had few metals, the modern universe must contain significantly more, allowing metallicity to serve as a proxy for stellar evolution. By analyzing spinning stars with low metallicity, they sought insights into the lifespan of the early universe’s rotating stars.

Following the GENEC simulations, the researchers observed distinct differences in the fates of rotating versus non-rotating stars. Spinning massive stars were more likely to collapse into black holes while being less prone to massive supernova eruptions or transitioning into dense neutron stars. The research indicated that very massive, non-rotating stars with low metallicity tend to explode as supernovae, whereas those with high metallicity collapse into black holes.

The researchers proposed that this intricate relationship arises because rotating stars tend to have more of their material mixed, increasing the fusion potential in their cores. However, this rotational dynamic can also lead to the ejection of more outer material, ultimately reducing the fusion resources available in the core.

An additional complicating factor arises from the frequent occurrence of multiple massive stars in close proximity, forming a binary system. In these scenarios, stars can exchange mass, either gaining or losing material. The researchers suggest that because massive stars in binary systems may shed mass before their lifetimes conclude, their model could underestimate the frequency of massive stars evolving into neutron stars rather than exploding or collapsing into black holes.

In summary, the team concluded that rotation intricately influences star evolution. While rotation increases the likelihood of a massive star undergoing certain outcomes, such as collapsing into a black hole, factors like composition and initial mass significantly affect its destiny. Acknowledging the multitude of variables, the researchers emphasized that the next phase in understanding massive stars’ fates should focus on identifying stars in binary systems.

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Source: sciworthy.com

Milky Way Black Holes Could Be Rotating at Their Limit

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SEI 255742397

Image of Sagittarius A*, the black hole at the center of the Milky Way galaxy

EHT

At the core of our Galaxy lies an extraordinary rotating entity: a black hole that appears to be spinning near its maximum velocity.

Michael Jansen from Radboud University in the Netherlands and his team investigated black holes in the center of the Milky Way, specifically Sagittarius A*, utilizing data gathered by a collective network known as the Event Horizon Telescope (EHT). To tackle the intricacies of the data, they opted for artificial intelligence methods.

Initially, they simulated approximately one million black holes using established mathematical models, a computational endeavor that necessitated millions of hours on supercomputers. These simulations served as training data for a type of AI known as neural networks, enabling them to assess the properties of black holes based on empirical observations. Subsequently, they fed the AI with data on Sagittarius A* collected by the EHT throughout 2017.

The AI determined that Sagittarius A* is rotating at 80-90% of its theoretical maximum speed. It also indicated to the researchers that none of the currently available magnetic field models adequately describe the characteristics of this black hole, highlighting the need for additional mathematical modeling. Janssen notes that earlier studies had merely narrowed down the potential characteristics of Sagittarius A*, such as its rotation speed and surrounding magnetic fields, while this new methodology has refined those estimates.

Dimitrios Psaltis from Georgia Tech in Atlanta remarked that some of the findings were unexpectedly counterintuitive. Previous analyses had not clarified whether black hole spins could be accurately discerned from EHT data.

While earlier research suggested that Sagittarius A* might be spinning at significant speeds,
Mizuno Yuishi from Zhejiang University in Shanghai, China, noted that there is still room for enhancement in the computational models applied in this new analysis. “Our theoretical model is still not perfect,” he acknowledged.

However, both Mizuno and Psaltis agree that integrating AI into the study of exotic cosmic entities like black holes is increasingly essential. “We possess a wealth of data and numerous models, and we require a contemporary approach to merge the two,” Psaltis states. “This is precisely where machine learning proves to be transformative.”

Yet, this integration presents unique challenges, as AI work necessitates verification to mitigate potential inaccuracies and errors in subsequent analysis.

Janssen and his team have conducted numerous verification checks, including testing the AI with specially designed simulation data. They are also evaluating data from subsequent EHT operations and will be analyzing new findings from observatory results, he explains.

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Source: www.newscientist.com

Astronomers find farthest rotating disk galaxy ever observed: REBELS-25

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According to one researcher, REBELS-25 existed until 700 million years after the Big Bang. paper Published in Royal Astronomical Society Monthly Notices.

This image shows the galaxy REBELS-25, observed by ALMA, superimposed on infrared images of other stars and galaxies. This infrared image was taken by ESO's Visible Infrared Survey Telescope for Astronomy (VISTA). Image credits: ALMA / ESO / National Astronomical Observatory of Japan / NRAO / Roland others. / Dunlop others. / Cas / Kare.

The galaxies we see today are very different from the chaotic, clumpy galaxies that astronomers typically observed in the early universe.

These messy early galaxies merge with each other and evolve into smoother shapes at an incredibly slow pace.

Current theory suggests that it would take billions of years of evolution for galaxies to become as ordered as our Milky Way, a rotating disk with an orderly structure like spiral arms.

However, the detection of REBELS-25 casts doubt on that timescale.

“Our understanding of galaxy formation predicts that most early galaxies appear small and messy,” said Dr Jacqueline Hodge, an astronomer at Leiden University.

In their study, Dr. Hodge and colleagues found that REBELS-25 existed at redshift z = 7.3 (when the universe was only 700 million years old), making it the most distant object ever discovered. They discovered that it was a strongly rotating disk galaxy.

“Seeing galaxies so similar to our own Milky Way and with strong rotational dominance adds to our understanding of how galaxies in the early universe evolved into the ordered galaxies of today's universe. It raises questions,” says Lucy Roland, a PhD student at Leiden University. University.

REBELS-25 was detected by the authors using the Atacama Large Millimeter/Submillimeter Array (ALMA).

To precisely identify the galaxy's structure and motion, they conducted follow-up observations at higher resolution with ALMA, confirming its record-breaking nature.

Surprisingly, the data suggested more developed features similar to the Milky Way, such as an elongated central bar and spiral arms, but more observations are needed to confirm this. Probably.

“Finding further evidence of a more evolved structure would be an interesting discovery, as this would be the most distant galaxy in which such a structure has been observed to date,” Rowland said.

“These future observations from REBELS-25, along with other discoveries of early rotating galaxies, could change our understanding of early galaxy formation and the evolution of the universe as a whole.”

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Lucy E. Rowland others. REBELS-25: Dynamically cold disk galaxy discovered at z = 7.31. MNRASpublished online October 7, 2024. doi: 10.1093/mnras/stae2217

Source: www.sci.news

Astronomers find record-breaking slowest rotating neutron star emitting radio waves

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Neutron stars typically spin quickly, taking just a few seconds or even a fraction of a second to complete one revolution around their axis, but one neutron star labeled ASKAP J1935+2148 bucks this rule, emitting radio signals at a relatively slow interval of 53.8 minutes.

Artist's impression of a neutron star. Image courtesy of Sci.News.

“We're used to extreme examples when studying radio-emitting neutron stars, so the discovery of such a compact star that is still emitting radio waves despite rotating slowly was unexpected,” said Professor Ben Stappers, from the University of Manchester.

“This new generation of radio telescopes demonstrates that pushing the boundaries of our search space will reveal surprises that will shake up our understanding.”

At the end of their lives, massive stars use up all their fuel and undergo a spectacular explosion called a supernova.

What remains is a stellar remnant called a neutron star, which consists of trillions of neutrons packed into an extremely dense sphere with a mass 1.4 times that of the Sun, packed into a radius of just 10 km.

Astronomers detected an unexpected radio signal from ASKAP J1935+2148 that traveled about 16,000 light-years to Earth.

The nature of its radio emission and the rate of change of its rotation period suggest that it is a neutron star, but further study is needed to confirm what this object is.

“This discovery relied on the complementary capabilities of the ASKAP and MeerKAT telescopes, combined with our ability to probe these objects on timescales of minutes, and examine how their radiation changes from second to second,” said Dr Kaustubh Rajwade, an astronomer at the University of Oxford.

“Such synergies can shed new light on how these compact objects evolve.”

ASKAP J1935+2148 was detected by CSIRO's ASKAP radio telescope in the Wadjari Yamatji region of Western Australia.

“What's interesting is that this object exhibits three different radiation states, each with completely different properties to the others,” said Dr Manisha Caleb, an astronomer at the University of Sydney.

“The MeerKAT radio telescope in South Africa played a key role in distinguishing between these states.”

“If the signals had not come from the same point in the sky, it would be hard to believe that it was the same object producing these different signals.”

“Until the arrival of these new telescopes, the dynamic radio sky was relatively unexplored,” said Professor Tara Murphy, from the University of Sydney.

“Now we can look deeply and frequently see a variety of unusual phenomena.”

“These events give us insight into how physics works in extreme environments.”

This discovery paper In the journal Natural Astronomy.

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M. Caleb othersA radio transient phenomenon in which the radiation state switches with a period of 54 minutes. Nat AstronPublished online June 5, 2024; doi: 10.1038/s41550-024-02277-w

Source: www.sci.news

NASA’s Rotating Explosive Rocket Engine Takes Flight with 3D Printing Technology

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by Ramon J. Osorio, NASA Marshall Space Flight Center December 26, 2023

Engineers at NASA’s Marshall Space Flight Center in Huntsville, Alabama, successfully completed a 251-second high-temperature combustion test of a full-scale rotary explosion rocket engine combustor in fall 2023, achieving more than 5,800 pounds of thrust. Credit: NASA

NASAMarshall Space Flight Center tested a 3D-printed Rotating Explosive Rocket Engine (RDRE) for more than four minutes and was able to generate significant thrust. This test is essential for deep space missions and represents a step forward in NASA’s development of an efficient propulsion system for the Moon. Mars vision.

NASA has achieved a new benchmark in the development of an innovative propulsion system called the Rotating Explosive Rocket Engine (RDRE). Engineers at NASA’s Marshall Space Flight Center in Huntsville, Alabama, tested his new 3D-printed RDRE for 251 seconds (or over four minutes) and were able to generate more than 5,800 pounds of thrust.

This type of sustained burn emulates the typical requirements for a lander touchdown or deep space burn that could set a spacecraft on a course from the Moon to Mars, the center said. said Thomas Teasley, lead Marshall combustion equipment engineer.

RDRE’s first high-temperature fire test was conducted in Marshall in the summer of 2022 in partnership with In Space LLC and Purdue University (Lafayette, Indiana). The test generated more than 4,000 pounds of thrust for nearly a minute. The main objective of the latest tests was to extend the combustor to different thrust classes, support all types of engine systems, and maximize the diversity of missions it can deliver, from landers to upper stages to supersonics. Teasley said the key is to better understand how to increase the Reverse propulsion is a deceleration technique that has the potential to land larger payloads, and even humans, on the surface of Mars.

Test stand video taken at NASA’s Marshall Space Flight Center in Huntsville, Alabama, shows the ignition of a full-size rotary-explosion rocket engine combustor that ignited for a record 251 seconds and achieved more than 5,800 pounds of thrust. It is shown.

“RDRE significantly increases design efficiency,” he said. “This shows we are getting closer to developing lightweight propulsion systems that will allow us to send more mass and payloads into deep space, a critical component for NASA. From the moon to Mars vision. “

Engineers at NASA’s Glenn Research Center in Cleveland; Venus Aerospace, Houston, Texas, is working with NASA Marshall to identify ways to scale the technology for higher performance.

RDRE is managed and funded by the Game Changing Development Program within NASA’s Space Technology Mission Directorate.

Source: scitechdaily.com