Thursday, May 12, 2022

Astronomers present first image of black hole at center of Milky Way

Scientists theorize that "supermassive black holes" lie at the center of all galaxies, including our own. "Sagittarius A*" is orders of magnitude more dense than the sun but it's also quite some distance from Earth.

A link of eight radio observatories form the virtual telescope that captured the first visual images of Sagittarius A*

An international team of astronomers on Thursday unveiled the first image of a supermassive black hole called Sagittarius A*, or Sgr A*, at the center of the Milky Way.

It comes three years after the very first image of a black hole from a distant galaxy was released.

Black holes are regions of space whose gravity pull is so strong that nothing can escape it, including light.

"For decades, we have known about a compact object that is at the heart of our galaxy that is four million times more massive than our Sun," Harvard University astronomer Sara Issaoun told a press conference in Garching, Germany.

"Today, right this moment, we have direct evidence that this object is a black hole," she added.

Within Milky Way but far away

The image was captured by the Event Horizon Telescope Collaborative and is the first direct visual rendering of the presence of this object, which is invisible to the naked eye.

The black hole itself is not depicted by the telescope's image, but rather the glowing gas that encircles it in a bright ring of light.

Sagittarius A* is thought be several million times more dense than Earth's sun.

Although it is within our Milky Way galaxy, the black hole is located an estimated 27,000 light years from earth — by comparison, the sun is a little more than 8 light minutes away from Earth.

EHT captured the image

To capture the image from Sagittarius A*, scientists had to link eight giant radio observatories across the planet to form a single "Earth-sized" virtual telescope, the Event Horizon Telescope (EHT).

"The EHT can see three million times sharper than the human eye," German scientist Thomas Krichbaum of the Max Planck Institute for Radio Astronomy told reporters.

To capture the image, the EHT observed Sgr A* for multiple nights for many hours in a row, the same process used to produce the first image of a black hole in 2019.

Despite being closer to Earth, it was still difficult to capture the image. The brightness and pattern of the gas surrounding Sgr A* changed rapidly as the team observed it, "a bit like trying to take a clear picture of a puppy quickly chasing its tail," said EHT scientist Chi-kwan Chan of the University of Arizona.

jcg/msh (AFP, AP, dpa)

Astronomers reveal first image of black hole at Milky Way's centre

Issued on: 12/05/2022

Paris (AFP) – An international team of astronomers on Thursday unveiled the first image of a supermassive black hole at the centre of our own Milky Way galaxy -- a cosmic body known as Sagittarius A*.

The image -- produced by a global team of scientists known as the Event Horizon Telescope (EHT) Collaboration -- is the first, direct visual confirmation of the presence of this invisible object, and comes three years after the very first image of a black hole from a distant galaxy.

Black holes are regions of space where the pull of gravity is so intense that nothing can escape, including light.

The image thus depicts not the black hole itself, because it is completely dark, but the glowing gas that encircles the phenomenon -- which is four million times more massive than our Sun -- in a bright ring of bending light.

"These unprecedented observations have greatly improved our understanding of what happens at the very centre of our galaxy," said EHT project scientist Geoffrey Bower, of Taiwan's Academia Sinica.

Bower also said in a statement provided by the French National Centre for Scientific Research (CNRS) that the observations had offered "new insights on how these giant black holes interact with their surroundings".

The results are published in The Astrophysical Journal Letters.

Virtual telescope

Sagittarius A* -- abbreviated to Sgr A*, which is pronounced "sadge-ay-star" -- owes its name to its detection in the direction of the constellation Sagittarius.

Its existence has been assumed since 1974, with the detection of an unusual radio source at the centre of the galaxy.

In the 1990s, astronomers mapped the orbits of the brightest stars near the centre of the Milky Way, confirming the presence of a supermassive compact object there -- work that led to the 2020 Nobel Prize in Physics.

Though the presence of a black hole was thought to be the only plausible explanation, the new image provides the first direct visual proof.

Because it is 27,000 light years from Earth, it appears the same size in the sky as a donut on the Moon.

Capturing images of such a faraway object required linking eight giant radio observatories across the planet to form a single "Earth-sized" virtual telescope called the EHT.

These included the Institute for Millimetre Radio Astronomy (IRAM) 30-meter telescope in Spain, the most sensitive single antenna in the EHT network.

The EHT gazed at Sgr A* across multiple nights for many hours in a row -- a similar idea to long-exposure photography and the same process used to produce the first image of a black hole, released in 2019.

That black hole is called M87* because it is in the Messier 87 galaxy.
Moving target

The two black holes bear striking similarities, despite the fact that Sgr A* is 2,000 times smaller than M87*.

"Close to the edge of these black holes, they look amazingly similar," said Sera Markoff, co-chair of the EHT Science Council, and a professor at the University of Amsterdam.

Both behaved as predicted by Einstein's 1915 theory of General Relativity, which holds that the force of gravity results from the curvature of space and time, and cosmic objects change this geometry.

Despite the fact Sgr A* is much closer to us, imaging it presented unique challenges.

Gas in the vicinity of both black holes moves at the same speed, close to the speed of light. But while it took days and weeks to orbit the larger M87*, it completed rounds of Sgr A* in just minutes.

The researchers had to develop complex new tools to account for the moving targets.

The resulting image -- the work of more than 300 researchers across 80 countries over a period of five years -- is an average of multiple images that revealed the invisible monster lurking at the centre of the galaxy.

Scientists are now eager to compare the two black holes to test theories about how gasses behave around them -- a poorly understood phenomenon thought to play a role in the formation of new stars and galaxies.

Probing black holes -- in particular their infinitely small and dense centers known as singularities, where Einstein's equations break down -- could help physicists deepen their understanding of gravity and develop a more advanced theory.

© 2022 AFP

Event Horizon Telescope unveils image of black hole at center of Milky Way

The Event Horizon Project on Thursday, May 12, 2022, released the first image first look at the Milky Way black hole, Sagittarius A*, which required eight telescopes around the world and decades or work, according to researchers.

Photo by EHT Collaboration/Twitter

ORLANDO, Fla., May 12 (UPI) -- Astronomers who work on the Event Horizon Telescope project revealed the first-ever image of the supermassive black hole in the heart of the Milky Way galaxy.

Researchers presented the new findings at a multi-continent press conference with multiple live streams online.

"This is the first image of the black hole at the center of our galaxy," Sara Issaoun, an astronomer at Harvard's Center for Astrophysics, said during the press conference.

"For decades we have known about this compact object, but today, at this moment, we have direct evidence of its existence," Issaoun said.

The telescope, a series of eight synchronized radio telescopes spread across the globe, in 2019 produced the first-ever close-up image of a black hole.

Decades of data indicate that a cosmic monster -- a super massive black hole named Sagittarius A* -- lurks at the heart of the Milky Way, which follows the expectation that most other galaxies across the universe have them, too, the astronomers said.

RELATED Phenomenon thought to be closest black hole is actually a 'stellar vampire'

The telescope has been peering into center of the galaxy for several weeks, with many scientists speculating that the news could be the first-ever image of the Milky Way's galactic center.

"We've combined eight of the world's greatest telescopes to take this picture," José L. Gómez, a research scientist of the Institute of Astrophysics of Andalucía, said during the press conference.

"It was like trying to take a picture of a child running at night," Gómez said.

RELATED Supermassive black hole spotted hiding in cosmic dust 47M light-years from Earth

The image released in 2019 was of a different supermassive black hole, 53 million light-years from the Milky Way, in a galaxy known as Messier 87, or M87.

From the images, astronomers can compare the two objects. The images look strikingly similar, but the black holes are very different. For instance, SgrA* is approximately a million times less massive than the one in M87, and it also consumes gas at a much slower rate.

"Despite all these differences, the images look very similar," Issaoun said. "This reveals to us a key aspect of black holes: no matter their size or environment, once you arrive at the edge of a black hole, gravity takes over."

Researchers said that these ground-breaking mages are only possible with a telescope like the EHT. By combining the power of multiple radio telescopes around the globe, the team has created one super telescope that they can use to learn more about black holes.

In the image, radio waves create the glow around the dark heart of the black hole, which is called its shadow, which can provide astronomers with details about the black hole's properties.

"The size of a black hole shadow is proportional to its mass," Issaoun said. "We've determined that the size of SgrA* is indeed four million times larger than the size of the sun."

Issaoun said that this discovery is exciting because it confirms predictions that are based on stellar orbits.

In 2019, the team who captured the image of the M87 black hole, were able to make similar measurements, gleaning information on its magnetic field and its surrounding environment.

More recently, the suite of telescopes has increased in number, increasing to 11, which will help improve future images of SgrA* and other black holes.

Caltech researchers help generate first image of black hole at the center of our galaxy

Peer-Reviewed Publication

CALIFORNIA INSTITUTE OF TECHNOLOGY

A multi-institution collaboration that includes a Caltech-led imaging team has generated the first image of the supermassive black hole at the center of the Milky Way galaxy.

This result provides conclusive evidence that the body, known as Sagittarius A* (Sgr A*, pronounced "sadge-ay-star"), is indeed a black hole and yields valuable clues about the workings of such massive objects, which are thought to reside at the center of most galaxies.

The Sgr A* image was produced by an international research team, called the Event Horizon Telescope (EHT) Collaboration, consisting of more than 300 researchers from 80 institutions around the world. The result includes key contributions from an imaging team led by Caltech's Katherine L. (Katie) Bouman together with Kazunori Akiyama of MIT Haystack Observatory and José L. Gómez of Instituto de Astrofísica de Andalucía in Spain.

So far, the most convincing evidence that Sgr A* is a supermassive black hole has been provided by Caltech alumna Andrea Ghez (MS '89, PhD '92) of the University of California, Los Angeles, and Reinhard Genzel of the Max Planck Institute for Extraterrestrial Physics in Germany and University of California, Berkeley, whose work revealed that Sgr A* is a compact object that has a mass nearly four million times that of the sun. The discovery earned Ghez and Genzel—together with Roger Penrose of the University of Oxford for related advances in the understanding of black holes—the 2020 Nobel Prize in Physics.

The new EHT image of Sgr A* shows that the 4 million solar masses are constrained within a diameter smaller than Mercury's orbit, providing clearer evidence that the object is indeed a black hole.

This is the second-ever image taken of a black hole; in 2019, the EHT collaboration released an image of a black hole named M87*, at the center of the more distant Messier 87 galaxy.

Taking an image of Sgr A* at 27,000 light-years away from Earth is akin to taking a photo of a single grain of salt in New York City using a camera in Los Angeles. Taking an image of an object that appears that small requires an Earth-sized telescope—or data from many telescopes tiled evenly across the entire Earth. Since the EHT was not able to accomplish this impossible feat, it instead collected data from eight radio observatories scattered across the globe to form a single "Earth-sized" virtual telescope.

"This image from the Event Horizon Telescope required more than just snapping a picture from telescopes on high mountaintops. It is the product of both technically challenging telescope observations and innovative computational algorithms," Bouman said at a press conference announcing the new image. "Taking this picture of our black hole proved even more challenging than imaging the M87 black hole." While working on the M87 image, Bouman joined Caltech's faculty. She arrived on campus in 2019, shortly after the image's publication.

Joining Bouman, who is an assistant professor of computing and mathematical sciences, electrical engineering and astronomy; a Rosenberg Scholar; and an investigator at the Heritage Medical Research Institute, were former Caltech postdoctoral researcher He Sun and current Caltech postdoctoral researchers Aviad Levis and Junhan Kim.

Imaging A Black Hole

Although we cannot see the black hole itself because it is completely dark, we can see a telltale ring of glowing gas surrounding a dark central region called a "shadow." The size of the shadow observed, which theory says depends primarily on the black hole mass, precisely matched the mass estimated by prior observations. The new view captures light bent by the powerful gravity of the black hole, which is four million times more massive than our sun.

The team collected entire nights' worth of data over the course of multiple days -- a bit like a traditional camera with a long exposure time. Members of the EHT went to the ends of the earth, literally, to collect these measurements; Caltech's Kim, for example, helped prepare a telescope near the South Pole to observe with the EHT.

Because the data came from only a small number of telescopes peering at an object far away, the EHT team was left with incomplete data to use to construct the image of Sgr A*. That sparse and noisy data creates uncertainty, meaning that more than one image that could explain the data EHT gathered. And to make imaging the black hole even more challenging, Sgr A* is far more dynamic than M87*, with a bright ring of swirling gases that changes on a minute-by-minute basis. "With EHT, we're using telescopes scattered across the globe, each capturing data from the target at various points during the night as the earth rotates," Levis says. "When the target we are observing changes during that time—as it did for Sgr A*—it makes the problem much more complicated."

To reconstruct an image, the EHT team developed computational imaging algorithms capable of making inferences to fill in the blanks in the data that had been gathered. The team discovered that multiple ring geometries could explain the Sgr A* data, as well as some geometries that do not look ring-like at all. To better understand how the imaging algorithms worked on data from an evolving target, Levis built a synthetic model of variable structure (akin to water swirling around a drain) that was based on statistics taken from the real data about Sgr A* that EHT had gathered. The model was then used to exhaustively test EHT's imaging methods and identify the best settings to recover an accurate image.

"Through literally years of exhaustive tests on both real and synthetic data we are now confident that there is compelling evidence that the true underlying source has a ring structure," Bouman says.

Although non-ring geometries cannot be fully discarded, the statistical analysis performed by the team suggests that they are very unlikely -- the EHT results provide compelling evidence that the Sgr A* image is dominated by a bright emission ring about 50 microarcseconds in diameter, Bouman says.

After determining that Sgr A*'s image geometry is likely a ring, the EHT used a number of cutting-edge tools to estimate the uncertainty in the recovered structure. Former postdoc Sun, now starting a faculty position at Peking University, used a deep-learning method developed at Caltech to analyze the data and quantify various aspects of the black hole, including its diameter and the amount of asymmetry in the ring of bright gas surrounding it.

"We not only recovered an image of Sgr A*, but also characterized the uncertainty of features in the image," says Sun. "This analysis helped the team deliver scientific results with some guarantees."

Next Steps

The next step in future work is to make a movie of the black hole, showing it as it changes over time, which could yield insight into the way gas behaves as it swirls around a black hole, and would also help estimate the spin of the black hole itself. (Static images give an estimate of the mass, but if scientists know both the mass and the spin of the black hole they can better test Einstein's theory of general relativity and the theory that a black hole's spin and mass should fully describe how it affects its environment.)

In October, EHT member Antonio Fuentes, currently at Instituto de Astrofísica de Andalucía-CSIC in Spain, will join Caltech as a postdoctoral researcher. Fuentes and Bouman are currently developing methods that will allow them to piece together snapshots of Sgr A* to form a movie by imposing frame-to-frame continuity.

That work has already begun to yield results: By running these methods on 100-minute chunks of the Sgr A* data from April 6 and 7 of 2017, the researchers were able to create a number of different movies that could possibly fit the observed data. This analysis revealed that, although Sgr A* appeared fairly static on April 6 during these 100 minutes, during the same time period on April 7 it showed possible signs of significant evolution. However, while the EHT data shows detectable signs of image variability, the current data does not reliably constrain the underlying image evolution.

"This analysis provides a promising starting point for future studies of evolution seen in Sgr A* EHT observations when we have the opportunity to observe with more telescopes," Bouman says.

Moving forward, a portion of the EHT team, dubbed ngEHT (for Next Generation Event Horizon Telescope), has been awarded funding from the National Science Foundation (NSF) to determine the best locations for telescopes to create an Earth-sized lens through which to view the universe. Already, Caltech's Owens Valley Radio Observatory (OVRO) has joined the EHT team, with Vikram Ravi, assistant professor of astronomy at Caltech, leading the effort to include one of OVRO's 10-meter radio dishes in the EHT network by 2024. EHT is funded by multiple agencies, including the NSF.

DOI

10.3847/2041-8213/ac6429

METHOD OF RESEARCH

Observational study

ARTICLE TITLE

There are 10 articles, all under the heading "Focus on First Sgr A* Results from the Event Horizon Telescope"

ARTICLE PUBLICATION DATE

12-May-2022

Sagittarius A* revealed

Astronomers reveal first image of the black hole at the heart of our galaxy

Reports and Proceedings

UNIVERSITY OF CALIFORNIA - SANTA BARBARA

UC Santa Barbara and Las Cumbres Observatory graduate student Joseph Farah participated this morning in the press conference in Washington D.C. this morning, where astronomers unveiled the first image of the supermassive black hole at the center of our own Milky Way galaxy. This result provides overwhelming evidence that the object is indeed a black hole and yields valuable clues about the workings of such giants, which are thought to reside at the center of most galaxies. The image was produced by a global research team called the Event Horizon Telescope (EHT) Collaboration, using observations from a worldwide network of radio telescopes.

The image is a long-anticipated look at the massive object that sits at the very center of our galaxy. Scientists had previously seen stars orbiting around something invisible, compact, and very massive at the center of the Milky Way. This strongly suggested that this object — known as Sagittarius A* (Sgr A*, pronounced “sadge-ay-star”) — is a black hole, and today’s image provides the first direct visual evidence of it.

Although we cannot see the black hole itself, because it is completely dark, glowing gas around it reveals a telltale signature: a dark central region (called a “shadow”) surrounded by a bright ring-like structure. The new view captures light bent by the powerful gravity of the black hole, which is four million times more massive than our Sun.

“We were stunned by how well the size of the ring agreed with predictions from Einstein’s Theory of General Relativity,” said EHT Project Scientist Geoffrey Bower from the Institute of Astronomy and Astrophysics, Academia Sinica, Taipei. "These unprecedented observations have greatly improved our understanding of what happens at the very center of our galaxy, and offer new insights on how these giant black holes interact with their surroundings.” The EHT team's results are being published today in a special issue of The Astrophysical Journal Letters.

Because the black hole is about 27,000 light-years away from Earth, it appears to us to have about the same size in the sky as a donut on the Moon. To image it, the team created the powerful EHT, which linked together eight existing radio observatories across the planet to form a single “Earth-sized” virtual telescope [1]. The EHT observed Sgr A* on multiple nights, collecting data for many hours in a row, similar to using a long exposure time on a camera.

Farah devised a new technique for producing a dynamical movie representation of the black hole Sgr A*. He is the lead author on the paper released today, Selective dynamical imaging of interferometric data, in the special issue of The Astrophysical Journal Letters. Now a member in the lab of UCSB/LCO astronomy professor Andy Howell, Farah conducted much of the work for this project as an undergrad at University of Massachusetts, Boston.

The breakthrough follows the EHT collaboration’s 2019 release of the first image of a black hole, called M87*, at the center of the more distant Messier 87 galaxy.

The two black holes look remarkably similar, even though our galaxy’s black hole is more than a thousand times smaller and less massive than M87* [2]. "We have two completely different types of galaxies and two very different black hole masses, but close to the edge of these black holes they look amazingly similar,” says Sera Markoff, co-chair of the EHT Science Council and a professor of theoretical astrophysics at the University of Amsterdam, the Netherlands. "This tells us that General Relativity governs these objects up close, and any differences we see further away must be due to differences in the material that surrounds the black holes.”

This achievement was considerably more difficult than for M87*, even though Sgr A* is much closer to us. EHT scientist Chi-kwan (‘CK’) Chan, from Steward Observatory and Department of Astronomy and the Data Science Institute of the University of Arizona, explains: “The gas in the vicinity of the black holes moves at the same speed — nearly as fast as light — around both Sgr A* and M87*. But where gas takes days to weeks to orbit the larger M87*, in the much smaller Sgr A* it completes an orbit in mere minutes. This means the brightness and pattern of the gas around Sgr A* was changing rapidly as the EHT Collaboration was observing it — a bit like trying to take a clear picture of a puppy quickly chasing its tail.”

The researchers had to develop sophisticated new tools that accounted for the gas movement around Sgr A*. While M87* was an easier, steadier target, with nearly all images looking the same, that was not the case for Sgr A*. The image of the Sgr A* black hole is an average of the different images the team extracted, finally revealing the giant lurking at the center of our galaxy for the first time.

The effort was made possible through the ingenuity of more than 300 researchers from 80 institutes around the world that together make up the EHT Collaboration. In addition to developing complex tools to overcome the challenges of imaging Sgr A*, the team worked rigorously for five years, using supercomputers to combine and analyze their data, all while compiling an unprecedented library of simulated black holes to compare with the observations. Mr. Farah was part of the team that produced the image of the black hole M87* and he applied his knowledge from that work to developing the tools to generate dynamic images of Sgr A*.

Scientists are particularly excited to finally have images of two black holes of very different sizes, which offers the opportunity to understand how they compare and contrast. They have also begun to use the new data to test theories and models of how gas behaves around supermassive black holes. This process is not yet fully understood but is thought to play a key role in shaping the formation and evolution of galaxies.

“Now we can study the differences between these two supermassive black holes to gain valuable new clues about how this important process works,” said EHT scientist Keiichi Asada from the Institute of Astronomy and Astrophysics, Academia Sinica, Taipei. “We have images for two black holes — one at the large end and one at the small end of supermassive black holes in the Universe — so we can go a lot further in testing how gravity behaves in these extreme environments than ever before.”

Progress on the EHT continues: a major observation campaign in March 2022 included more telescopes than ever before. The ongoing expansion of the EHT network and significant technological upgrades will allow scientists to share even more impressive images as well as movies of black holes in the near future.

Farah is excited about the success of this endeavor, “I can’t believe how quickly the project grew from analyzing the exciting-but-preliminary initial datasets to seeing the beautiful shadow reconstruct before our eyes. It’s the only thing that seems to evolve faster than Sgr A*! What a privilege it has been to be a part of this wonderful project, with all of our wonderful collaborators.” He is grateful to the National Science Foundation for supporting his work through a graduate research fellowship.

Making of the image of the black hole at the center of the Milky Way
The Event Horizon Telescope (EHT) Collaboration has created a single image (top frame) of the supermassive black hole at the center of our galaxy, called Sagittarius A* (or Sgr A* for short), by combining images extracted from the EHT observations.

The main image was produced by averaging together thousands of images created using different computational methods — all of which accurately fit the EHT data. This averaged image retains features more commonly seen in the varied images, and suppresses features that appear infrequently.

The images can also be clustered into four groups based on similar features. An averaged, representative image for each of the four clusters is shown in the bottom row. Three of the clusters show a ring structure but, with differently distributed brightness around the ring. The fourth cluster contains images that also fit the data but do not appear ring-like.

The bar graphs show the relative number of images belonging to each cluster. Thousands of images fell into each of the first three clusters, while the fourth and smallest cluster contains only hundreds of images. The heights of the bars indicate the relative "weights," or contributions, of each cluster to the averaged image at top.

Notes

[1] The individual telescopes involved in the EHT in April 2017, when the observations were conducted, were: the Atacama Large Millimeter/submillimeter Array (ALMA), the Atacama Pathfinder Experiment (APEX), the IRAM 30-meter Telescope, the James Clerk Maxwell Telescope (JCMT), the Large Millimeter Telescope Alfonso Serrano (LMT), the Submillimeter Array (SMA), the UArizona Submillimeter Telescope (SMT), the South Pole Telescope (SPT). Since then, the EHT has added the Greenland Telescope (GLT), the NOrthern Extended Millimeter Array (NOEMA) and the UArizona 12-meter Telescope on Kitt Peak to its network.

ALMA is a partnership of the European Southern Observatory (ESO; Europe, representing its member states), the U.S. National Science Foundation (NSF), and the National Institutes of Natural Sciences (NINS) of Japan, together with the National Research Council (Canada), the Ministry of Science and Technology (MOST; Taiwan), Academia Sinica Institute of Astronomy and Astrophysics (ASIAA; Taiwan), and Korea Astronomy and Space Science Institute (KASI; Republic of Korea), in cooperation with the Republic of Chile. The Joint ALMA Observatory is operated by ESO, the Associated Universities, Inc./National Radio Astronomy Observatory (AUI/NRAO) and the National Astronomical Observatory of Japan (NAOJ). APEX, a collaboration between the Max Planck Institute for Radio Astronomy (Germany), the Onsala Space Observatory (Sweden) and ESO, is operated by ESO. The 30-meter Telescope is operated by IRAM (the IRAM Partner Organizations are MPG (Germany), CNRS (France) and IGN (Spain)). The JCMT is operated by the East Asian Observatory on behalf of the Center for Astronomical Mega-Science of the Chinese Academy of Sciences, NAOJ, ASIAA, KASI, the National Astronomical Research Institute of Thailand, and organizations in the United Kingdom and Canada. The LMT is operated by INAOE and UMass, the SMA is operated by Center for Astrophysics | Harvard & Smithsonian and ASIAA and the UArizona SMT is operated by the University of Arizona. The SPT is operated by the University of Chicago with specialized EHT instrumentation provided by the University of Arizona.

The Greenland Telescope (GLT) is operated by ASIAA and the Smithsonian Astrophysical Observatory (SAO). The GLT is part of the ALMA-Taiwan project, and is supported in part by the Academia Sinica (AS) and MOST. NOEMA is operated by IRAM and the UArizona 12-meter telescope at Kitt Peak is operated by the University of Arizona.

[2] Black holes are the only objects we know of where mass scales with size. A black hole a thousand times smaller than another is also a thousand times less massive.

Astronomers reveal first image of the black hole at the heart of our galaxy

First direct visual evidence – ring-like structure like M87* - Theoretical Physicists of Goethe University Frankfurt instrumental in interpreting the data

Peer-Reviewed Publication

GOETHE UNIVERSITY FRANKFURT

Simulation of the Accretion Disk around the Black Hole Sgr A* — IMAGE: EXAMPLE OF A SIMULATION OF HOW THE GAS ORBITS THE BLACK HOLE IN THE CENTER OF OUR MILKY WAY AND EMITS RADIO WAVES AT 1.3 MM. view more
CREDIT: YOUNSI, FROMM, MIZUNO & REZZOLLA (UNIVERSITY COLLEGE LONDON, GOETHE UNIVERSITY FRANKFURT

FRANKFURT. The image is a long-anticipated look at the massive object that sits at the very centre of our galaxy. Scientists had previously seen stars orbiting around something invisible, compact, and very massive at the centre of the Milky Way. This strongly suggested that this object — known as Sagittarius A* (Sgr A*, pronounced "sadge-ay-star") — is a black hole, and today’s image provides the first direct visual evidence of it.

Although we cannot see the black hole itself, because it is completely dark, glowing gas around it reveals a tell-tale signature: a dark central region (called a “shadow”) surrounded by a bright ring-like structure. The new view captures light bent by the powerful gravity of the black hole, which is four million times more massive than our Sun.

“We were stunned by how well the size of the ring agreed with predictions from Einstein’s theory of general relativity,” says EHT Project Scientist Geoffrey Bower from the Institute of Astronomy and Astrophysics, Academia Sinica, Taipei. “These unprecedented observations have greatly improved our understanding of what happens at the very centre of our galaxy and offer new insights on how these giant black holes interact with their surroundings.”

The enormous amount of observational data collected had to be interpreted theoretically. For this, a research team led by theoretical astrophysicist Luciano Rezzolla from Goethe University Frankfurt used supercomputers to simulate how a black hole could look like when observed by the EHT – based on what had already been known about Sgr A*. In this way, the scientists created a library of millions of images. Then, they compared this image library with the thousands of different images of the EHT to deduce the properties of Sgr A*.

The breakthrough follows the EHT Collaboration’s 2019 release of the first image of a black hole, called M87*, at the centre of the more distant Messier 87 galaxy.

The two black holes look remarkably similar, even though our galaxy’s black hole is more than a thousand times smaller and less massive than M87* [2]. “We have two completely different types of galaxies and two very different black hole masses, but close to the edge of these black holes they look amazingly similar,” says Sera Markoff, Vice Chair of the EHT Science Council and a professor of theoretical astrophysics at the University of Amsterdam, the Netherlands. “This tells us that general relativity governs these objects up close, and any differences we see further away must be due to differences in the material that surrounds the black holes.”

This achievement was considerably more difficult than for M87*, even though Sgr A* is much closer to us. EHT scientist Chi-kwan (‘CK’) Chan, from Steward Observatory, the Department of Astronomy and the Data Science Institute at the University of Arizona, US, explains: “The gas in the vicinity of the black holes moves at the same speed — nearly as fast as light — around both Sgr A* and M87*. But where gas takes days to weeks to orbit the larger M87*, in the much smaller Sgr A* it completes an orbit in mere minutes. This means the brightness and pattern of the gas around Sgr A* was changing rapidly as the EHT Collaboration was observing it — a bit like trying to take a clear picture of a puppy quickly chasing its tail.”

The effort was made possible through the ingenuity of more than 300 researchers from 80 institutes around the world that together make up the EHT Collaboration. In addition to developing complex tools to overcome the challenges of imaging Sgr A*, the team worked rigorously for five years, using supercomputers to combine and analyse their data, all while compiling an unprecedented library of simulated black holes to compare with the observations.

Luciano Rezzolla, professor of Theoretical Astrophysics at Goethe University Frankfurt, explains: “The mass and distance of the object were known very precisely before our observations. We thus used these tight constraints on the size of the shadow to rule out other compact objects – such as boson stars or wormholes – and conclude that: ‘What we're seeing definitely looks like a black hole!’”

Using advanced numerical codes, theorists in Frankfurt have performed extensive calculations on the properties of the plasma accreting onto the black hole. Rezzolla: “We managed to calculate three million synthetic images varying the accretion and radiation emission models, and considering the variations seen by observers at different inclinations with respect to the black hole.”

This last operation was necessary because the image of a black hole can be radically different when seen by observers at different inclinations. “Indeed, a reason why our images of Sgr A* and M87* are rather similar is because we’re seeing the two black holes from an almost identical angle,” Rezzolla explains.

“To understand how the EHT has produced an image of Sgr A* one can think of producing a picture of a mountain peak based on a time-lapse video. While most of the time the peak will be visible in the time-lapse video, there are times when it is not because it is obscured by clouds. On average, however, the peak is clearly there. Something similar is true also for Sgr A*, whose observations lead to thousands of images which have been collected in four classes and then averaged according to their properties. The end result is a clear first image of the black hole at the centre of the Milky Way.” Rezzolla concludes.

“Now we can study the differences between these two supermassive black holes to gain valuable new clues about how this important process works,” says EHT scientist Keiichi Asada from the Institute of Astronomy and Astrophysics, Academia Sinica, Taipei. “We have images for two black holes — one at the large end and one at the small end of supermassive black holes in the Universe — so we can go a lot further in testing how gravity behaves in these extreme environments than ever before.”

To Goethe University are associated a number of scientists in the EHT Collaboration. Together with Professor Luciano Rezzolla, Dr Alejandro Cruz Orsorio, Dr Prashant Kocherlakota and Kotaro Moriyama, also Prof Mariafelicia De Laurentis (University of Naples), Dr Christian Fromm (University of Würzburg), Prof Roman Gold (University of Southern Denmark), Dr Antonios Nathanail (University of Athens), and Dr Ziri Younsi (University College London) have provided essential contributions to the theoretical research in the EHT Collaboration.

This work has been supported by the European Research Council.

Notes:

ALMA is a partnership of the European Southern Observatory (ESO; Europe, representing its member states), the U.S. National Science Foundation (NSF) and the National Institutes of Natural Sciences (NINS) of Japan, together with the National Research Council (Canada), the Ministry of Science and Technology (MOST; Taiwan), Academia Sinica Institute of Astronomy and Astrophysics (ASIAA; Taiwan) and Korea Astronomy and Space Science Institute (KASI; Republic of Korea), in cooperation with the Republic of Chile. The Joint ALMA Observatory is operated by ESO, the Associated Universities, Inc./National Radio Astronomy Observatory (AUI/NRAO) and the National Astronomical Observatory of Japan (NAOJ). APEX, a collaboration between the Max Planck Institute for Radio Astronomy (Germany), the Onsala Space Observatory (Sweden) and ESO, is operated by ESO. The 30-meter telescope is operated by IRAM (the IRAM partner organizations are MPG (Germany), CNRS (France) and IGN (Spain)). The JCMT is operated by the East Asian Observatory on behalf of the Center for Astronomical Mega-Science of the Chinese Academy of Sciences, NAOJ, ASIAA, KASI, the National Astronomical Research Institute of Thailand and organizations in the United Kingdom and Canada. The LMT is operated by INAOE and UMass, the SMA is operated by Center for Astrophysics | Harvard & Smithsonian and ASIAA, and the UArizona SMT is operated by the University of Arizona. The SPT is operated by the University of Chicago with specialized EHT instrumentation provided by the University of Arizona.

[2] Black holes are the only objects we know of where mass scales with size. A black hole a thousand times smaller than another is also a thousand times less massive.

Youtube-Playlist Black Hole

Find further animations on how the picture of the black hole in the center of our galaxy was made on the Goethe University’s playlist „Black Hole“

https://youtube.com/playlist?list=PLn5gYfEKIag8nps1GKLqUW35AOgQY7aM2

Further pictures and video clips provided by EHT Collaboration:

https://eventhorizontelescope.teamwork.com/#notebooks/240600 (Animationen)
https://eventhorizontelescope.teamwork.com/#notebooks/240540 (Bilder)

Websites

https://eventhorizontelescope.org/ EHT Website
https://blackholecam.org/ Black Hole Cam-Project

JOURNAL

The Astrophysical Journal Letters

DOI

10.3847/2041-8213/ac6674

METHOD OF RESEARCH

Observational study

ARTICLE TITLE

First Sagittarius A* Event Horizon Telescope Results. I. The Shadow of the Supermassive Black Hole in the Center of the Milky Way

ARTICLE PUBLICATION DATE

12-May-2022

Scientists grow plants in lunar dirt, next stop moon

By MARCIA DUNN

1 of 7

In this 2021 photo provided by the University of Florida, Institute of Food and Agricultural Sciences, a researcher harvests a thale cress plant growing in lunar soil, at a laboratory in Gainesville, Fla. For the first time, scientists have used lunar soil collected by long-ago moonwalkers to grow plants, with results promising enough that NASA and others already are envisioning hothouses on the moon for the next generation of lunar explorers.

(Tyler Jones/UF/IFAS via AP)

CAPE CANAVERAL, Fla. (AP) — For the first time, scientists have grown plants in soil from the moon collected by NASA’s Apollo astronauts.

Researchers had no idea if anything would sprout in the harsh moon dirt and wanted to see if it could be used to grow food by the next generation of lunar explorers. The results stunned them.

“Holy cow. Plants actually grow in lunar stuff. Are you kidding me?” said Robert Ferl of the University of Florida’s Institute of Food and Agricultural Sciences.

Ferl and his colleagues planted thale cress in moon soil returned by Apollo 11′s Neil Armstrong and Buzz Aldrin, and other moonwalkers. The good news: All of the seeds sprouted.

The downside was that after the first week, the coarseness and other properties of the lunar soil stressed the small, flowering weeds so much that they grew more slowly than seedlings planted in fake moon dirt from Earth. Most of the moon plants ended up stunted.

Results were published Thursday in Communications Biology.

In this 2021 photo provided by the University of Florida, Institute of Food and Agricultural Sciences, a researcher places a thale cress plant grown during a lunar soil experiment in a vial for genetic analysis, at a laboratory in Gainesville, Fla. For the first time, scientists have used lunar soil collected by long-ago moonwalkers to grow plants, with results promising enough that NASA and others already are envisioning hothouses on the moon for the next generation of lunar explorers.

(Tyler Jones/UF/IFAS via AP)

The longer the soil was exposed to punishing cosmic radiation and solar wind on the moon, the worse the plants seemed to do. The Apollo 11 samples — exposed a couple billion years longer to the elements because of the Sea of Tranquility’s older surface — were the least conducive for growth, according to scientists.

“This is a big step forward to know that you can grow plants,” said Simon Gilroy, a space plant biologist at the University of Wisconsin-Madison, who had no role in the study. “The real next step is to go and do it on the surface of the moon.”

Moon dirt is full of tiny, glass fragments from micrometeorite impacts that got everywhere in the Apollo lunar landers and wore down the moonwalkers’ spacesuits.

One solution might be to use younger geologic spots on the moon, like lava flows, for digging up planting soil. The environment also could be tweaked, altering the nutrient mixture or adjusting the artificial lighting,

Only 842 pounds (382 kilograms) of moon rocks and soil were brought back by six Apollo crews. Some of the earliest moon dust was sprinkled on plants under quarantine with the Apollo astronauts in Houston after returning from the moon.

Most of the lunar stash remained locked away, forcing researchers to experiment with simulated soil made of volcanic ash on Earth. NASA finally doled out 12 grams to the University of Florida researchers early last year, and the long-awaited planting took place last May in a lab.

NASA said the timing for such an experiment was finally right, with the space agency looking to put astronauts back on the moon in a few years.

The ideal situation would be for future astronauts to tap into the endless supply of available local dirt for indoor planting versus setting up a hydroponic, or all-water, system, scientists said.

“The fact that anything grew means that we have a really good starting point, and now the question is how do we optimize and improve,” said Sharmila Bhattacharya, NASA’s program scientist for space biology,

The Florida scientists hope to recycle their lunar soil later this year, planting more thale cress before possibly moving on to other vegetation.

___

The Associated Press Health and Science Department receives support from the Howard Hughes Medical Institute’s Department of Science Education. The AP is solely responsible for all content.

NASA says 'monster marsquake' on Red Planet strongest quake ever measured off Earth

1/4

NASA's Mars Perseverance rover snapped this photo on the surface of the Red Planet on February 24, 2021. Scientists said this week that the marsquake registered a magnitude of 5.0.

File Photo by NASA/UPI | License Photo

May 11 (UPI) -- NASA's state-of-the-art equipment that's sitting on the surface of Mars has detected the most powerful earthquake ever recorded on the Red Planet -- or any other world away from the Earth, for that matter.

Scientists at NASA's Jet Propulsion Laboratory in California said that the InSight Mars lander measured the "monster" marsquake -- which was a 5.0-magnitude temblor.

The InSight lander, which has been on Mars since late 2018, has a highly sensitive seismometer to study the deep interior of the planet. The previous record-holder was a 4.2-magnitude quake that occurred last August.

Scientists said that the new strong quake was measured on May 4 -- 1,222 Martian days, or sols, since the lander has been there.

"Since we set our seismometer in December 2018, we've been waiting for 'the big one,'" Bruce Banerdt, InSight principal investigator at JPL, said in a statement.

NASA's InSight Mars Lander captured this image not long after it landed on the Red Planet on November 26, 2018. Equipment on the lander measured the 5.0-magnitude quake on May 4. File Photo by NASA/UPI

"This quake is sure to provide a view into the planet like no other. Scientists will be analyzing this data to learn new things about Mars for years to come."

As seismic waves pass through or reflect off material in Mars' crust, mantle and core, they change in ways that seismologists can study to determine the depth and composition of those layers, scientists said.

"What scientists learn about the structure of Mars can help them better understand the formation of all rocky worlds, including Earth and its Moon," NASA said in a statement.

"The science team will need to study this new quake further before being able to provide details such as its location, the nature of its source, and what it might tell us about the interior of Mars.

The InSight lander is part of NASA's Discovery program, which is exploring detailed facts about the Red Planet.

Chinese rover detects water existed on Mars more recently than thought

Scientists used instruments to analyze rocks and minerals on the surface of Mars,

finding evidence there was substantial liquid water on the planet more recently

than previously thought.

Photo courtesy of the China National Space Administration

May 11 (UPI) -- Nearly one year after landing on Mars, scientists say China's Zhurong rover collected data indicating water may have existed on the planet over a longer period of time than previously thought.

A study published Wednesday in the journal Science Advances said Zhurong detected evidence that the Utopia Planitia basin had "substantial" liquid water during its most recent epoch of geologic history -- the Amazonian. Scientists previously believed this time period, about 700 million years ago, to be cold and dry and liquid water activities to be "extremely limited."

Before assessing the new data, scientists believed that Mars lost much of its water after its Hesperian period, about 3 billion years ago.

The Zhurong rover touched down on Mars' surface May 15 as part of the Tianwen-1 mission. The main point of the mission was to search for signs of life, ice and water.

Scientists from China's National Space Science Center and the Chinese Academy of Sciences analyzed data gathered from a laser-induced breakdown spectrometer, telescopic microimaging camera and short-wave infrared spectrometer to study minerals to determine the amount of liquid water that would have been at the site millions of years ago.

1/8

NASA’s Curiosity Mars rover used two different cameras to create this panoramic selfie, comprised of 60 images, in front of Mont Mercou, a rock outcrop that stands 20 feet tall on March 26, 2021, the 3,070th Martian day, or sol, of the mission. These were combined with 11 images taken by the Mastcam on the mast, or "head," of the rover on March 16. The hole visible to the left of the rover is where its robotic drill sampled a rock nicknamed "Nontron." The Curiosity team is nicknaming features in this part of Mars using names from the region around the village of Nontron in southwestern France.

Photo courtesy of NASA/JPL-Caltech/MSSS

Wealthy nations carving up space and its riches, leaving others behind

By Theodora Ogden, Arizona State University
THE CONVERSATION

A Mercury Redstone stands silhouetted on Complex 5 as SpaceX launches 53 Starlink satellites from the Kennedy Space Center in Florida on Friday.
RELATED SpaceX rocket launch leaves 'space jellyfish' in its wake

Photo by Joe Marino/UPI | License Photo

May 12 (UPI) -- Satellites help run the Internet and television and are central to the Global Positioning System. They enable modern weather forecasting, help scientists track environmental degradation and play a huge role in modern military technology.

Nations that don't have their own satellites providing these services rely on other countries. For those that want to develop their own satellite infrastructure, options are running out as space fills up.

I am a research fellow at Arizona State University, studying the wider benefits of space and ways to make it more accessible to developing countries.

Inequity is playing out in access to satellites. In the not-so-distant future, the ability to extract resources from the moon and asteroids could become a major point of difference between the space haves and have-nots. As policies emerge, there is the risk that these inequities become permanent.

RELATED Experts issue call to regulate space debris as levels of junk mount

Where to park satellite

Thanks to the rapid commercialization, miniaturization and plummeting costs of satellite technology in recent years, more countries are able to reap the benefits of space.

CubeSats are small, cheap, customizable satellites that are simple enough to be built by high school students. Companies such as SpaceX can launch one of these satellites into orbit for relatively cheap -- from $1,300 per pound. However, there are only so many places to "park" a satellite in orbit around Earth, and these are quickly filling up.

RELATED Kamala Harris announces U.S. ban on anti-satellite missile tests

The best parking is in geostationary orbit, around 22,250 miles above the equator. A satellite in geostationary orbit rotates at the same rate as Earth, remaining directly above a single location on Earth's surface -- which can be very useful for telecommunications, broadcasting and weather satellites.

There are only 1,800 geostationary orbital slots, and as of February, 541 of them were occupied by active satellites. Countries and private companies have claimed most of the unoccupied slots that offer access to major markets, and the satellites to fill them are being assembled or awaiting launch. If, for example, a new spacefaring nation wants to put a weather satellite over a specific spot in the Atlantic Ocean that is already claimed, they would either have to choose a less optimal location for the satellite or buy services from the country occupying the spot they wanted.

Orbital slots are allocated by an agency of the United Nations called the International Telecommunication Union. Slots are free, but they go to countries on a first-come, first-served basis. When a satellite reaches the end of its 15- to 20-year lifespan, a country can simply replace it and renew its hold on the slot. This effectively allows countries to keep these positions indefinitely. Countries that have the technology to utilize geostationary orbit have a major advantage over those that do not.

While geostationary orbital slots are the most useful and limited, there are many other orbits around Earth. These, too, are filling up -- adding to the growing problem of space debris.

Low-Earth orbit is around 1,000 miles above the surface. Satellites in low-Earth orbit are moving fast in a highly congested environment. While this may be a good place for Earth imaging satellites, it is not ideal for single communication satellites -- like those used to broadcast television, radio and the Internet.

Low-Earth orbit can be used for communications if multiple satellites work together to form a constellation. Companies like SpaceX and Blue Origin are working on projects to put thousands of satellites into low-Earth orbit over the next few years to provide Internet across the globe. The first generation of SpaceX's Starlink consists of 1,926 satellites, and the second generation will add another 30,000 to orbit.

At the current rate, the major space players are rapidly occupying geostationary and low-Earth orbits, potentially monopolizing access to important satellite capabilities and adding to space junk.

Access to resources

Orbital slots are an area where inequity exists today. The future of space could be a gold rush for resources -- and not everyone will benefit.

Asteroids hold astounding amounts of valuable minerals and metals. Later this year, NASA is launching a probe to explore an asteroid named 16 Psyche, which scientists estimate contains over $10 quintillion worth of iron. Tapping huge resource deposits like this and transporting them to Earth could provide massive boosts to the economies of spacefaring nations while disrupting the economies of countries that depend on exporting minerals and metals.

Another highly valuable resource in space is helium-3, a rare version of helium that scientists think could be used in nuclear fusion reactions without producing radioactive waste. While there are considerable technological obstacles to overcome before helium-3 is a feasible energy source, if it works, there are enough deposits on the moon and elsewhere in the solar system to satisfy Earth's energy requirements for several centuries. If powerful spacefaring countries develop the technology to use and mine helium-3 -- and choose not to share the benefits with other nations -- it could result in lasting inequities.

Existing international space laws are not well suited to handle the complicated web of private companies and nations competing for resources in space. Countries are organizing into groups -- or "space blocs" -- that are uniting on goals and rules for future space missions. Two notable space blocs are planning missions to set up bases and potential mining operations on the moon: the Artemis Accords, led by the United States, as well as joint Chinese and Russian plans.

Right now, the major players in space are establishing the norms for exploiting resources. There is a risk that instead of focusing on what is best for everyone on Earth, competition will drive these decisions, damaging the space environment and causing conflict. History shows that it is hard to challenge international norms once they are established.

Moving forward

Access to space is critical for the functioning of a modern nation. Space access will only become more important as humanity rapidly advances toward a future of space hotels and colonies on Mars.

The 1967 Outer Space Treaty, the founding document of space law, says that space should be used "for the benefit and in the interests of all countries." The policies taking shape today will dictate whether this is the case in the future.

Theodora Ogden is a research fellow in emerging space countries at Arizona State University.

This article is republished from The Conversation under a Creative Commons license. Read the original article.

The views and opinions expressed in this commentary are solely those of the author.

Almost 5,000 were injured in Astroworld stampede last fall,

court filing says

Ten people died from injuries received when hoards of fans rushed the stage at the festival last November 5 as rapper Travis Scott started performing. File Photo by Ken Murray/EPA-EFE

May 12 (UPI) -- The deadly stampede at the Astroworld Music Festival in Texas last year caused thousands of injuries to concert-goers, some of whom needed to be hospitalized, according to a court filing that's part of the legal actions against the organizers.

Attorneys for the thousands of people who are suing Astroworld promoters said in the filing Thursday that more than 700 of the injuries required extensive medical treatment while those to another 1,600 were a little less severe.

Injuries to another 2,500 people are still being reviewed, the attorneys said

Rapper Travis Scott performs at the MTV Video Music Awards at Radio City Music Hall in New York City on August 20, 2018. Scott and organizers of Astroworld are named in dozens of lawsuits related to the deadly stampede last November.

File Photo by John Angelillo/UPI

Ten people died from injuries received when hoards of fans rushed the stage at the festival at Houston's NRG Stadium last Nov. 5 as rapper Travis Scott started performing.

Hundreds of lawsuits were filed against Scott, Live Nation, concert promoter Scoremore LLC and others just a few days after the accident. All of them are now consolidated under one judge. They allege gross negligence and failures in planning and staging the concert safely.

Earlier this month, Scott performed publicly for the first time since the Astroworld concert when he took the stage at the Billboard Awards. He said immediately following the stampede that he was "devastated" by what happened.

"I have a responsibility to figure out what happened here. I have a responsibility to figure out the solution," he told a radio show a few weeks after the accident, according to ABC News.

Costa Rica declares emergency after gov't systems hit by notorious hacker gang

U.S. officials say that a notorious hacker gang is behind perhaps the "costliest strain of ransomware ever documented."

Authorities said that a user linked to Conti, one of the world's most active

ransomware gangs, claimed responsibility for the attack on a dark web site.

File Photo by Ritchie B. Tongo/EPA

May 12 (UPI) -- Officials have declared a state of emergency in Costa Rica after government computers there were targeted by a crippling ransomware attack, authorities said.

Investigators said that hackers tapped into the country's finance ministry computer system a month ago and the attack quickly spread to other areas, including government science, technology and telecommunications infrastructure and Costa Rica's National Meteorological Institute.

"The government has been really, really affected," Leon Weinstok, director of Costa Rican law firm BLP, said according to NBC News. "It is impossible to quantify the losses at this time."

New Costa Rican President Rodrigo Chaves Robles, who took office this week, said that there are many cybercriminals and cyberterrorists in the Central American nation.

The hackers who breached the systems had attempted to extort the Costa Rican government and former President Carlos Alvarado out of $10 million, officials said.

Authorities said that a user linked to Conti, one of the world's most active ransomware gangs, claimed responsibility for the attack on a dark web site. Last week, the U.S. State Department offered a $10 million reward for information leading to perpetrators associated with Conti.

"[This] ransomware group has been responsible for hundreds of ransomware incidents over the past two years," department spokesman Ned Price said in a statement.

Price added that federal investigators believe there have been more than 1,000 cyberattacks worldwide worth $150 million associated with Conti, and that the group is behind the "costliest strain of ransomware ever documented."

California Gov. Newsom allots $57M to strengthen abortion access

California Gov. Gavin Newsom poses for a photo with supporters of Planned Parenthood LA earlier this month.

Photo courtesy of Planned Parenthood LA/Twitter

May 11 (UPI) -- As the Supreme Court appears poised to strike down abortion's federal protections, California Gov. Gavin Newsom on Wednesday announced an additional nearly $60 million to strengthen the state's access to the medical procedure and to cover an anticipated influx of out-of-state patients seeking it.

The Democratic governor announced the $57 million increase to his Reproductive Health Package unveiled in January, bumping the proposal's top line to $125 million.

From the new funding, $40 million has been set aside for grants to reproductive healthcare providers to help cover the cost of abortion services for low- and moderate-income individuals without health insurance and those from out of state.

An additional $15 million has also been allotted for grants to community reproductive health, rights and justice organizations for sexual and reproductive health outreach and education with another $1 million for a website to inform the public on state abortion laws, reproductive healthcare providers and ways to cover reproductive health services.

"California will not stand idly by as extremists roll back our basic constitutional rights," he said in a statement. "We're going to fight like hell, making sure that all women -- not just those in California -- know that this state continues to recognize and protect their fundamental rights."

He also said they will offer incentives to court businesses to relocate to California from states with abortion bans and laws restricting the rights of LGBTQ people. His office further explained that the incentive programs will provide additional consideration for such companies that "share California's values."

"We're expanding access to these critical services, welcoming businesses and their employees fleeing anti-abortion states and reaffirming our commitment to continuing to work closely with the legislature and reproductive rights stakeholders to further solidify California's leadership on abortion rights," Newsom said.

The announcement was made as Republican-led states have sought through legislature to increasingly restrict access to abortion and nearly two weeks after a draft opinion by the Supreme Court overturning the landmark Roe vs. Wade that provided the medical procedure with federal protections was leaked to the press.

Democrats nationwide protested the decision with Newsom announcing an amendment to enshrine the right to access abortion in the state's constitution hours after the draft decision was leaked

On Wednesday, the divided U.S. Senate voted down a largely symbolic Democrat-pushed proposal to codify Roe vs. Wade into federal law.

Planned Parenthood President and CEO Jodi Hicks called the budget increase announced Wednesday not only a step toward maintaining access to abortion in California but an expansion of it.

"The more than $100 million in investments will go a long way in protecting and expanding sexual and reproductive healthcare, including abortion access, for those who live here and those who may be forced to seek care here," Hicks said in a statement. "As we prepare for the Supreme Court to overturn Roe vs. Wade and witness other states stripping access to abortion, this investment is crucial to ensuring the future of abortion access in California."

According to the Guttmacher Institute, last year was "the worst" for abortion rights in 50 years with 108 abortion restrictions enacted by state legislatures. The previous high was 89 set in 2011.

So far this year, 37 such restrictions have been enacted, it said.

NHL closing in on seeing its first female coach

By JOHN WAWROW

1 of 5

This image provided by Hockey Canada Images, Canada's assistant coach Kori Cheverie. Cheverie’s ascension coupled with the growing number of women entering pro hockey management and developmental roles has rapidly sped the timetable on when — not if — there will be a woman working behind an NHL bench.

(Dave Holland/Hockey Canada Images via AP)

Kori Cheverie reflects fondly on the conversations she had with her grandfather growing up in Nova Scotia, where he encouraged her to believe anything was attainable in sports.

First woman to play for the Toronto Blue Jays? Sure. Hoist the Stanley Cup over her head while representing the Toronto Maple Leafs? Go for it.

Though doing so as a player is now out of the question, Cheverie’s gender-breaking aspirations appear far more achievable today to the 34-year-old, who has spent the past five years chipping away at hockey’s male-only coaching barrier.

In 2017, Cheverie became the first female assistant coach of a men’s hockey team at the Canadian university level (at Ryerson). This month, after serving as an assistant on the Canadian women’s Olympic championship team, she completed a stint as Hockey Canada’s first woman behind the bench of a men’s team at the Under-18 world championships.

“It’s kind of funny, looking back and reflecting on those conversations as a kid, because I am the first to do quite a few things on the men’s side of hockey,” said Cheverie, recalling the talks with her grandfather, Jack Rehill. “They speak to the limitless childhood that I had growing up, and what I was told I could be capable of.”

And she’s not done dreaming.

Cheverie’s ascension coupled with the growing number of women entering pro hockey management and developmental roles has rapidly sped the timetable on when — not if — there will be a woman working behind an NHL bench.

As much as Pittsburgh Penguins president Brian Burke believes the glass ceiling should have been shattered yesterday, he balances his impatience by noting the inroads the league is making to blow up its image as an old boys club.

“I think it’s basically we’ve been bound by our past, which is white people playing hockey and going into management,” Burke told The Associated Press.

“It might be a slower build than people like,” he added. “But I’m greatly encouraged by the change in the last two years of the role of women in hockey, which has gone from nonexistent to significant in a very short time.”

In four years since Hayley Wickenheiser opened the door by becoming the Toronto Maple Leafs’ assistant director of player development, the league’s female hockey-related ranks have increased to nearly 30. And that doesn’t include five NHL teams featuring female presidents.

The Penguins are among the NHL teams leading the way. With two women already on their hockey staff, the Penguins expanded the list by naming U.S. Olympian Amanda Kessel as the first participant in the team’s executive management program last month. Vancouver is the first NHL team to hire not one but two assistant general managers in Cammi Granato and Emilie Castonguay.

“I think it’s pretty nearsighted if people didn’t think that ultimately there’d be some sort of equalization between genders, not just in hockey but in every industry,” NHL Coaches’ Association president Lindsay Artkin said. “It wouldn’t be unrealistic to see a female hired in the NHL after next season.”

The NHLCA has played a role in fast-tracking the movement. With the backing of her male coaching membership, Artkin launched a female developmental program two years ago.

The program identified 50 women —- including Cheverie — at various levels to work directly with NHL coaches in advanced training sessions. Aside from exchanging ideas, the program also provided women networking opportunities they previously lacked in getting on the radar as potential coaching candidates.

While Artkin said NHL coaches are impressed by the wealth of knowledge the women bring, the female participants find the sessions reinforced the belief of being equals when working with men.

“It’s absolutely validating,” said University of St. Thomas assistant women’s coach Bethany Brausen. “The terminology might be slightly different, but we’re all speaking the same language.”

Whatever apprehensions Brausen had about overseeing men melted away when one male coach said most players don’t care about gender but just one thing: Does the coaching make them better?

“That’s a very simple thing to say,” Brausen said. “But I think hearing a male, coaching at that level, explicitly say that, it’s `Of course.′ As soon as he said that, I’m like, `Why would it matter how you look or, frankly, what your background is?’”

A conversation during a 25-minute drive with Christine Bumstead was all it took to convince former Winnipeg Jets coach Paul Maurice how knowledgeable she was in recommending her to the program.

“Christine is going to be a great coach. She is one now,” Maurice said of Bumstead, who just completed her first year as an assistant for the University of Saskatchewan women’s team. “There’s a lot of really intelligent young coaches, some of them are male, some of them are female, and they now have an opportunity that just wasn’t there 20 years ago.”

He’s confident the gender barrier will be broken, much like other walls have fallen in recalling how Canadian Junior Hockey Leagues once shunned American-born players.

“If you’re not willing to change and evolve as a coach, you’re done,” Maurice said, before noting “men don’t have the market cornered on communication.”

“You listen to Jennifer Botterill on TV. She talks about the game differently,” he said of the Canadian Olympian-turned-broacaster. “It’s just a different perspective at times. It may or may not have anything to do with her being a women. But she’s interesting.”

The NHL has lagged behind North America’s three other major pro sports in hiring women.

In 2019, Rachel Balkovec became major league baseball’s first full-time female hitting coach and this year became the game’s first female minor league manager. The NBA featured seven female assistants this year. And the NFL’s ranks of female coaches grew to 12 last season.

NHL Commissioner Gary Bettman said he expects the process of women being hired as coaches to evolve, rather than imposing quotas or implementing rules.

“I’m hoping we don’t need that,” Bettman said. “I’m hoping that it evolves to the point where it just becomes a part of how you function where you don’t need arbitrary rules for people to be doing the right things.”

The chances of that happening have vastly improved, NHL vice president Kim Davis said, in crediting the developmental program for providing women direct access to those who have hiring authority.

“The fact that they have access and you have women in these roles, it’s going to ultimately result in those women ascending to these top positions as GMs, as coaches,” Davis said. “So I’m hugely encouraged by our progress. We have a lot more to do. By no means are we taking a victory lap.”

As much as Cheverie would most certainly like to be the first woman hired to coach in the NHL, she stressed the opportunity would have to be the right fit in working on a staff and a team open to hearing her voice.

“I would love to be in the NHL. Of course, I think, many female coaches would. But it’s not the be-all, end-all for me. I want to do the best that I can do,” she said.

“I’m really looking forward to the day where this isn’t a conversation,” Cheverie added. “I wish that day was today and it’s just us talking about a coach coaching a team and trying to help them win versus how does a female fit into a group of males in a sporting setting.”

___

AP Hockey Writer Stephen Whyno contributed.

___

More AP NHL: https://apnews.com/hub/nhl and https://twitter.com/AP_Sports

LA REVUE GAUCHE - Left Comment

Thursday, May 12, 2022

Caltech researchers help generate first image of black hole at the center of our galaxy

Imaging A Black Hole

Next Steps

DOI

METHOD OF RESEARCH

ARTICLE TITLE

ARTICLE PUBLICATION DATE

Sagittarius A* revealed

Astronomers reveal first image of the black hole at the heart of our galaxy

JOURNAL

DOI

METHOD OF RESEARCH

ARTICLE TITLE

ARTICLE PUBLICATION DATE

About Me