Wednesday, July 15, 2026

NASA’s Hubble Discovers First of Star Cluster’s Missing Black Holes - UNIVERSE

The massive globular star cluster Omega Centauri has puzzled astronomers for decades. It should be filled with black holes left behind by exploding stars, yet evidence for them is scarce. Now, astronomers using archival data from NASA’s Hubble Space Telescope and supportive observations from NASA’s James Webb Space Telescope have finally located their first stellar-mass black hole in this cluster. Discovering the first of this missing black hole population will help refine current theories on black hole formation within environments such as Omega Centauri. The team’s findings published Monday in The Astrophysical Journal Letters.

Omega Centauri is composed of 10 million gravitationally bound stars. Though the astronomical community previously found evidence with Hubble that an intermediate-mass black hole lurks at its center, models suggest this star cluster should also contain about 10,000 smaller, stellar-mass black holes. This notable population of black holes evaded detection in previous observational studies, which used the radial velocity method or looked for radio and X-ray emission from material falling onto black holes.

This new discovery features a different approach, known as astrometry, to measure very small movements of stars over time. By sifting through more than 20 years of Hubble archival data and pulling in recent Webb data to further refine their astrometric measurements, the team located a star orbiting an invisible object so hefty that it has to be a black hole. Dubbed oMEGACat BH-2, it is the first stellar-mass black hole detected in Omega Centauri, and it has some surprising qualities. oMEGACat BH-2 has a lower-than-expected mass and, with its visible star companion, the black hole-star duo has the longest orbital period of any black hole binary system known to date.

“With Hubble and Webb data, we were able to see the motion of the visible main sequence star that is part of this binary, which is about 18,000 light-years away in the dense environment of Omega Centauri,” said Matthew Whitaker of the University of Utah, Salt Lake City, lead author of the paper. “The precision of these measurements is incredible, down to a fraction of a pixel on Hubble and Webb’s detectors. It would not have been possible to find this black hole without these two space telescopes.”

Astronomers found Omega Centauri’s first stellar-mass black hole, which has a visible star companion that is shown in greater detail. They used 20-plus years of data from NASA’s Hubble Space Telescope and recent data from NASA’s James Webb Space Telescope to make the discovery.

Image: ESA, NASA, Maximilian Häberle (MPIA), Joseph DePasquale (STScI)

The team’s findings refine a past study by a different group of scientists that suggested this binary system included a neutron star. By expanding Hubble data from the earlier investigation with archival Hubble astrometric measurements from 2002 to 2023, and pulling in Webb near-infrared data to improve precision, the University of Utah-led team was able to better constrain the mass of the visible star’s dark companion, ruling out the neutron star possibility.

“While we already knew that the star was 0.78 solar masses, we can now calculate the black hole’s mass, which is 4.46 solar masses and therefore too heavy to be a neutron star. However, its mass is much lower than would be expected in a metal-poor environment like Omega Centauri. This is surprising and exciting,” said Anil Seth of the University of Utah, a coauthor of the study. “We now know that a metal-poor star is able to form a black hole like this, and we need to figure out how that happens. This detection is providing some data to those who do that kind of modeling.”

Long time coming

Based on the precise data from Hubble and Webb, the team could chart the star’s path over 20-plus years, during its closest approach to its black hole companion when it moved the fastest across the sky. From the extensive data, the team determined that the visible star orbits oMEGACat BH-2 once every 94 years, making it the longest-period black hole binary ever known.

Its long orbital period also gives a clue to the origin of this binary system. It was probably dynamically formed, meaning the star and its black hole companion did not start out together but rather found each other in this cluster. The researchers calculated that a system like oMEGACat BH-2 will survive for less than a billion years before it is torn apart by encounters with nearby stars, a much shorter span than the age of the cluster (approximately 12 billion years old).

“It's important to understand black hole populations in globular clusters because there's uncertainty about their physics and formation,” said Seth. “More specifically, understanding the process of forming black holes and then dynamically forming binaries is vital, because it affects our ability to interpret and understand gravitational wave events. Environments like Omega Centauri are the primary places where we think binaries are merging and creating these waves.”

The team’s discovery of stellar-mass black hole oMEGACat BH-2 with the Hubble-Webb dataset is just the start of finding these evasive black hole populations in globular star clusters.

“With Hubble and Webb, we can continue to look at Omega Centauri and expand our search for similar systems within other clusters,” said Whitaker. “We’re also very excited for the launch of NASA’s Nancy Grace Roman Space Telescope because it will image the crowded galactic bulge, including the galactic center, very regularly with Hubble-like resolution and with a much wider field of view. We’re hoping we’ll be able to find black hole binary systems like this one because of the regular cadence of Roman’s observations.” 

Source: NASA’s Hubble Discovers First of Star Cluster’s Missing Black Holes - NASA Science

Porous material could pull 1.8 liters of drinking water daily from dry air - Energy & Green Tech - Hi Tech & Innovation

Using a model, Kalle Mertin demonstrates the porous structure of CAU-10-H. His arm passing through the model illustrates the material's continuous, tube-like pores, where water molecules are adsorbed and released. Credit: Christina Anders, Uni Kiel

Researchers in chemistry and materials science at Kiel University are working with partners to develop new water sources for the Mediterranean region. "Regions like these are facing rising temperatures and declining rainfall. Our goal is to develop an environmentally friendly technology that converts water molecules from the air into drinking water," says Professor Norbert Stock from CAU's Institute of Inorganic Chemistry.

"Two new studies, published in the Journal of Materials Chemistry A and Industrial & Engineering Chemistry Research, describe how large quantities of the material can be produced and the efficiency of cooling devices can be improved."

The studies also show a new approach that enables the team to make water from the air available more efficiently and quickly than previous systems.

A sponge-like material with a high-tech structure

Materials belonging to the class of metal-organic frameworks (MOFs) behave much like a sponge: They can adsorb large amounts of water within a short time and release it again just as quickly. This is made possible by their extremely porous structure, which contains countless interconnected microscopic cavities. The 2025 Nobel Prize in Chemistry was awarded for fundamental research behind these materials.

Electrically conductive MOF–carbon foam composites for atmospheric water harvesting that can be regenerated by Joule heating or sunlight. Credit: Journal of Materials Chemistry A (2026). DOI: 10.1039/d6ta00544f

In Kiel, Stock's team is optimizing the synthesis of the MOF "CAU-10-H" specifically for water adsorption and heat transformation. The material is named after the place of discovery at Kiel University, its material number and the chemical symbol for hydrogen.

CAU-10-H captures water molecules within its porous structure at room temperature and relative humidity values of ≥18% and releases them again at around 70°C (158°F). By combining the material with conductive carbon structures, the researchers can accelerate this process even further.

The resulting composite material can be heated efficiently using electricity or sunlight. As a result, it releases the adsorbed water particularly quickly and operates in short, repeatable cycles.

Under dry conditions, the system continuously produces drinking water from the air and achieves a water uptake of up to 0.17 grams of water per gram of material. The cycles take only a few hours, enabling efficient, continuous operation. Under these conditions, 1 kilogram (2.2 pounds) of the composite material can potentially produce up to 1.8 liters (0.5 gallons) of water from the air per day.

"This makes the material particularly attractive for producing drinking water, even in arid regions," says first author Lasse Wegner.

At the same time, CAU-10-H also shows considerable potential for cooling applications. In adsorption cooling systems, it delivers up to three times the cooling performance of silica gel, a widely used desiccant based on silicon dioxide.

In the future, such systems could make use of waste heat, for example from data centers or bakeries. This significantly reduces the energy consumption of air conditioning systems compared with established technology and makes cooling more sustainable.

From the lab to industrial production

"We discovered CAU-10-H around 15 years ago, and since then its potential applications have been investigated around the world," says Stock, who has been conducting research on MOFs for more than two decades.

The team has now successfully transferred production to pilot scale—the intermediate step between laboratory research and industrial manufacturing. Led by Kalle Mertin, the researchers produced around 30 kilograms (66 pounds) of the material, approximately 60 times more than had previously been manufactured in the laboratory.

At the same time, they further optimized the production process based on a techno-economic analysis to demonstrate that manufacturing costs of $12 to $14 per kilogram are achievable.

"This brings practical applications of our materials within reach," says Stock. "We have shown that they not only work in the laboratory but can also be produced on an economically viable scale." 

Provided by Kiel University 

Source: Porous material could pull 1.8 liters of drinking water daily from dry air