Tuesday, May 26, 2026

A twinkling pulsar reveals invisible structures in space

The linear structure is the visible scattering of the pulsar PSR B1508+55, which is located at the center of the image. The invisible interstellar medium—the thin material between the stars—causes this distortion, which also results in changes in brightness over a period of several hours. The intensity of the radiation is color-coded and increases from violet through red to orange. © Tim Sprenger / MPIfR

The radio image from December 5, 2023, shows the point-like pulsar (center of the image), whose radiation is scattered into a line. The distinct shape indicates that the scattering gas between us and the pulsar is not randomly distributed. Instead, it exists in structures with a preferred orientation—such as folded thin layers. The image was obtained at radio frequencies between 1300 and 1425 megahertz. © Tim Sprenger / MPIfR


To the point:
  • An international team led by Tim Sprenger of the Max Planck Institute for Radio Astronomy (MPIfR) observed the flickering of a pulsar’s radio radiation with two of the world’s most powerful radio telescopes.

    •
  • The shape of the distorted image allows us to conclude that the thin gas between us and the stellar remnant is not randomly distributed, but rather exists in structures with a preferred orientation.

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  • The observational technique allows for the capture of high-resolution images without the need to link telescopes around the globe in a data- and computation-intensive manner.


Fluctuations in brightness and the elongated appearance of a stellar remnant indicate that its radiation is being scattered within an unidentified interstellar cloud located 430 light-years from Earth.

The twinkling stars in the night sky are not just beautiful to look at. Their flickering reveals something about the varying temperatures and densities in the layers of Earth’s atmosphere, which refract the light as it travels toward us. Certain stellar remnants that emit radio waves can exhibit a very similar effect. Although their radio waves—which have longer wavelengths than visible light—can penetrate Earth’s atmosphere almost undisturbed, they are scattered by the thin gas between the stars. Their twinkling—known as scintillation—thus provides unique insights into interstellar space.

An international team led by Tim Sprenger from the Max Planck Institute for Radio Astronomy (MPIfR) measured the flickering radio radiation from an object using an innovative observation technique. The results are published in the current issue of the journal Astronomy & Astrophysics.

Flickering Stellar Remnants

Scintillation occurs only in point sources, which is why distant stars twinkle but planets do not. In the radio spectrum, flickering can be observed in pulsars—the remnants of massive stars. They are among the most compact objects in the universe: the mass of an entire star is compressed into a sphere with the diameter of a major city. The radio signals emitted by pulsars fluctuate in brightness due to scintillation, and their position in the sky appears smeared. The pulsar observed in the current study is only the second one in which the distortion caused by scintillation could be directly imaged.

Unexpectedly straight

The research team led by Tim Sprenger observed the pulsar designated PSR B1508+55, located about 7,000 light-years away in the constellation Draco. In the long-exposure image, the pulsar appears distorted into a line. “Usually, one imagines that the pulsar is distorted into a blurred disk by random density fluctuations. Instead, the interstellar medium here seems to form ordered structures with a preferred orientation,” explains lead author Tim Sprenger. These could be, for example, parallel filaments or thin, folded layers.

Exactly what the structures look like in this case is not yet clear. This is partly because the observed scattering they cause is very small on an astronomical scale and difficult to observe. Of particular interest are small irregularities in the otherwise straight scattered line. “Observing the contrast between the primary linear image and its complex deviations is fascinating. It makes us wonder: what are the microscopic structures that created them—structures that elude our current picture of the interstellar medium?", adds co-author Xun Shi from Yunnan University in China. Using model calculations, it is at least possible to determine that the interstellar cloud is located about 430 light-years from Earth.

Groundbreaking Observation Technique

The scintillation of a pulsar causes such small positional changes that they cannot be spatially resolved with individual telescopes. The researchers therefore used a sophisticated observational technique and two of the world’s most powerful radio telescopes: The 100-meter Effelsberg radio telescope in Germany and the Five-hundred-meter Aperture Spherical radio Telescope (FAST) in China. Due to Earth's motion, when both telescopes are pointed simultaneously at PSR B1508+55, their positions change significantly over time.

This means that, over the course of a day, sometimes one telescope and sometimes the other sees the same flickering first, depending on whether Germany or China is currently pointing more in the direction of the Earth’s motion. From this, an image can be calculated. Co-author Olaf Wucknitz adds: “Taking advantage of the large distance between the two radio telescopes and of the Earth’s motion relative to the observed structures, we were able to achieve a resolution that is not possible with any other technique in the observed frequency range.”

At higher frequencies, comparable resolutions can be achieved by combining many telescopes around the world into a virtual telescope. This is technically complex, and the resulting data must be correlated in a time-consuming process. “The observation technique we used does not place high demands on the infrastructure. It works with locally processed data sets that we were able to merge using our standard laptops,” reports Tim Sprenger. Following this success, observations of additional pulsars are planned. These should then reveal more about the invisible structures of the interstellar medium. Michael Kramer, Executive Director of the MPIfR, points out that FAST is currently the most sensitive telescope in the world, emphasising: “This beautiful work demonstrates what’s possible when two of the most powerful instruments in the world are working together. Both telescopes are great, but their rare combination is even far better!”



Additional Information

The following scientists affiliated to the MPIfR are co-authors of this publication: Tim Sprenger and Olaf Wucknitz.


Contacts:

Dr. Tim Sprenger
Tel: +49 228 525-319
Email: tsprenger@mpifr-bonn.mpg.de

Dr. Olaf Wucknitz
Tel: +49 228 525-481
Email: wucknitz@mpifr-bonn.mpg.de

Dr. Nina Brinkmann
Press and Public Relations
Tel: +49 228 525-399
Email: brinkmann@mpifr-bonn.mpg.de


Original publication

Sprenger, T. et al.
Imaging without visibilities – FAST-Effelsberg scintillometry of PSR B1508+55
Astronomy & Astrophysics 709 (2026)

DOI


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Monday, May 25, 2026

The Origins of Nereid, Neptune's Most Eccentric Moon


Neptune

Short movie showing the orbits of Nereid, Triton, and the inner moons of Neptune. The innermost moons all orbit in the plane of Neptune's equator. Triton orbits the other way, with a significantly inclined orbit. Nereid is much further out, with a highly eccentric, or elliptical, orbit. Made using Universe Sandbox. Credit: M. Belyakov


Neptune, the farthest of the planets, acts like a shepherd for the outer solar system, gravitationally scattering distant asteroids known as Kuiper Belt Objects (KBOs). Understanding Neptune's history gives important clues to how the rest of the solar system evolved to its present state.

Neptune itself is unique—tilted 30 degrees on its side, it is host to a few unusual moons, including the Pluto-sized moon called Triton. Triton orbits Neptune backward, an indicator that it did not form around Neptune but was instead captured by Neptune's gravity after it formed elsewhere in the solar system. New observations coupled with simulations of Neptune's evolutionary history indicate that an oft-overlooked Neptunian moon called Nereid may reveal the planet's past.

The research was led by graduate student Matthew Belyakov and conducted as a collaboration between the laboratories of Professor of Planetary Science Konstantin Batygin (PhD '12), and Mike Brown, the Richard and Barbara Rosenberg Professor of Planetary Astronomy and Terence D. Barr Leadership Chair and director of the Center for Comparative Planetary Evolution. The work is reported in a paper appearing in Science Advances on May 20.

Jupiter, Saturn, and Uranus all have "typical" moon systems, with each planet possessing several large moons that orbit closely and along the host planet's equatorial plane, as well as many smaller moons, called irregular satellites, located farther out on tilted or "inclined" orbits. Neptune, on the other hand, has just one large moon, Triton, that contains 99.9 percent of the mass in its entire moon system. Triton's orbit is retrograde—it moves clockwise, while Neptune orbits the Sun counterclockwise. This means that Triton could not have coalesced in place, as Jupiter and Saturn's moons did, out of the disk of material orbiting counterclockwise around its planet. Instead, Triton is thought to be a Kuiper Belt Object, like Pluto, that was flung into Neptune's path and ensnared gravitationally.

Prior to Voyager 2's flyby of Neptune in August 1989, only one other moon was known around Neptune, Nereid. Discovered by Dutch astronomer Gerard Kuiper in 1949, Nereid has since presented a mystery. The moon follows an eccentric orbit, swinging around Neptune in an ellipse, and is far from its planet, but not nearly as distant as irregular satellites around the other giant planets. Interestingly, Nereid does not have a 14retrograde orbit like Triton, and its orbit is much less inclined than other irregular moons in the solar system. Given these details, scientists debated Nereid's origin for 70 years, unable to conclude whether the moon was captured or formed in place.

In 2024, Caltech graduate students Matthew Belyakov and M. Ryleigh Davis (MS '22) used the James Webb Space Telescope (JWST) to observe the Neptunian moon system, with Nereid as one of the targets. The team used JWST's near-infrared spectrograph, which splits light into its many wavelengths in order to obtain chemical information about astronomical targets. Nereid's spectrum appeared rather different from that of Kuiperbelt objects—Nereid was instead more similar to the moons of Uranus. Informed by the observational data, which hinted toward a noncaptured origin for Nereid, Belyakov then developed simulations of the evolution of Neptune's moons.

The simulations showed that as Triton crashed into the Neptunian system and was captured, existing Neptunian moons could have been kicked out on eccentric orbits that looked identical to ereid's. This suggests that Nereid formed in situ around Neptune, rather than being a captured foreign object.

"Understanding what transpired at Neptune is one of the ways that we can solve what happened in the early solar system, and Nereid is important for pinning down key events like Triton's capture," Belyakov says. "We're hoping this work motivates people to do creative observations of Nereid, even though it is faint and distant. It's just as important as Triton. I hope Nereid will be visited by a mission within my lifetime."

Without such a mission, much about Nereid is likely to remain a mystery.Voyager images of Nereid are only a few pixels across. In continuation of their work, the team aims to build more simulations to constrain the timing of Triton's capture and the possible configurations for the initial moon system around Neptune.

The paper is titled "Nereid as a Regular Satellite of Neptune." In addition to Belyakov, Batygin, Brown, and Davis, former Caltech graduate student Ian Wong (PhD '18), now of the Space Telescope Science Institute in Baltimore, Maryland, is a co-author. Funding was provided by NASA, the European Space Agency, and the Canadian Space Agency, which jointly operate JWST.

Written by Lori Dajose

Source: Caltech/News


Contact:

Lori Dajose
(626) 395‑1217
ldajose@caltech.edu

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Sunday, May 24, 2026

Gaze into the Crystal Ball Nebula and See the Light Emitted by a Dying Star 1500 Years Ago

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NGC 1514: The Crystal Ball Nebula

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The cosmic splendor of NGC 1514 is revealed in this new image from the Gemini North telescope in Hawai‘i

The 8.1-meter Gemini North telescope, located on the summit of Maunakea in Hawai‘i, has captured NGC 1514, nicknamed the Crystal Ball Nebula, in awe-inspiring detail. This nebula, with its mesmerizing glow of gas, harbors hints of a past stellar death, and its asymmetrical shell is now being shaped by the pair of binary stars that lie at its center.

NGC 1514, nicknamed the Crystal Ball Nebula, is showcased in this enchanting image captured by Gemini Multi-Object Spectrograph (GMOS) on the Gemini North telescope, located on Maunakea in Hawai‘i. Gemini North is one half of the International Gemini Observatory, partly funded by the U.S. National Science Foundation (NSF) and operated by NSF NOIRLab.

German–British astronomer William Herschel discovered the Crystal Ball Nebula in 1790. It’s located in the constellation Taurus, near the border of Perseus. While, culturally, crystal balls are known for divining the future, the Crystal Ball Nebula provides us with a snapshot of the final stages of a star’s life from long ago. It sits around 1500 light-years from Earth. This means the light captured in this image left its source around 1500 years ago, traveling across the Universe before finally reaching Gemini North.

The Crystal Ball Nebula is categorized as a planetary nebula, a nomenclature first presented by the nebula’s discoverer, William Herschel. He coined the term in the 1700s after spotting the spherical shape of these objects, which reminded him of planets. In reality, planets and planetary nebulae are unrelated.

Planetary nebulae form when a low- or intermediate-mass star ejects its outer layers near the end of its life, forming a somewhat spherical cloud of gas. They typically have smoother, spherical shapes, making the Crystal Ball Nebula unique for its bumpy shells of gas. As the central star casts away this gas, its inner core is exposed. Radiation from the core energizes the gas, giving it a scorching temperature and chromatic glow. The Crystal Ball Nebula, for example, has an estimated temperature of 15,000 K.

Herschel found this object fascinating, amazed by its faintly illuminated shell. Prior to its discovery, he believed that nebulae were collections of stars that were too far away to individually resolve. The distinct bright point at the heart of the gaseous shell shattered this theory. He wrote in 1791, “Our judgment I may venture to say, will be, that the nebulosity about the star is not of a starry nature.” He believed the illumination of the Crystal Ball Nebula came from a single star, not a far-off grouping.

While it may appear in this image as if there is a single shining light source at the heart of the Crystal Ball Nebula, as Herschel saw, it actually contains two stars. These two stars orbit each other with a period of around nine years — the longest known for any binary pair within a planetary nebula. Scientists believe that one of these stars, which was once several times more massive than our Sun, released its outer layers while in the throes of death. As the progenitor star and its binary companion orbit each other, they mold the expanding shell of gas with their strong, asymmetrical winds, forming the lumpy layers we see today.



More information
This image was produced by NSF NOIRLab’s Communication, Education & Engagement team, as part of the NOIRLab Legacy Imaging Program.

NSF NOIRLab, the U.S. National Science Foundation center for ground-based optical-infrared astronomy, operates the International Gemini Observatory (a facility of NSF, NRC–Canada, ANID–Chile, MCTIC–Brazil, MINCyT–Argentina, and KASI–Republic of Korea), NSF Kitt Peak National Observatory (KPNO), NSF Cerro Tololo Inter-American Observatory (CTIO), the Community Science and Data Center (CSDC), and NSF–DOE Vera C. Rubin Observatory (in cooperation with DOE’s SLAC National Accelerator Laboratory). It is managed by the Association of Universities for Research in Astronomy (AURA) under a cooperative agreement with NSF and is headquartered in Tucson, Arizona. 

The scientific community is honored to have the opportunity to conduct astronomical research on I’oligam Du’ag (Kitt Peak) in Arizona, on Maunakea in Hawai‘i, and on Cerro Tololo and Cerro Pachón in Chile. We recognize and acknowledge the very significant cultural role and reverence of I’oligam Du’ag to the Tohono O’odham Nation, and Maunakea to the Kanaka Maoli (Native Hawaiians) community.


Links

Contacts:

Josie Fenske
Public Information Officer
NSF NOIRLab
Email: josie.fenske@noirlab.edu

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Saturday, May 23, 2026

Playing Pool with Planets

An artist's impression of 10 hot Jupiters, one of the populations of Jupiter-sized planets.
Credit: ESA/Hubble & NASA; CC BY 4.0

An artist’s depiction of a hot Jupiter. These planets orbit extremely close to their host stars, but likely got to their locations by scattering inward from more distant orbits.  Credit: NASA/JPL-Caltech

A schematic showing where different planets ended up as a function of where they scattered from during their evolution.
Credit:: Esposito et al. 2026


Each Jupiter-size planet in the galaxy falls into one of three distinct categories: hot, warm, or cold. A new study suggests that despite the apparent differences between these populations, they may have all formed from the same underlying dynamical process: a game of pool played at planetary scales.

A Diversity of Jupiters

Though our solar system has only one Jupiter-size planet, elsewhere in the galaxy we have found three different species of these massive gas giants. Cold Jupiters closely resemble their namesake and orbit far from their host stars; hot Jupiters are the opposite and are found whipping around their stars on extremely close-in orbits. In between these are the warm Jupiters, which tend to orbit in the intermediate space between 0.1 and 1.0 au.

Though these three populations are defined by their orbital distances, they differ from each other in other ways as well. For example, hot Jupiters almost never have nearby companions; if there are any other planets circling the same star, they’re usually far-out cold Jupiters. They can also orbit in pretty much any direction, including opposite the direction of their star’s spin, and are usually on perfectly circular orbits. In contrast, warm Jupiters often have friends nearby, are much more aligned with their stars’ spins, and can have modest eccentricities.

Given these differences, it’s often thought that each of these populations arrived at its current location through different dynamical processes and that the history of the warm Jupiters is likely quite different from the history of the hot Jupiters. However, a new study led by Julia Esposito (Georgia Institute of Technology) has proposed an alternative view. Maybe these populations, though they appear different now, were all created by the same process: planet–planet scattering.

Virtual Planetary Billiards

Esposito and collaborators set up 1,500 virtual planetary systems with three massive planets each, then simulated how the orbits evolved before probing the final configurations. In crucial contrast to previous simulation studies, the team initialized their Jupiters across a range of different distances and included the effects of tides sapping energy from orbits of planets that got too close to their host stars.

At the end of the simulation, the team surveyed the digital carnage. Almost every virtual system ended with only two planets after either ejecting one away from the star or having two planets collide. But, remarkably, the remaining two-planet systems looked tantalizingly similar to what we actually observe, with a mix of hot, warm, and cold Jupiters. Even more exciting, the end populations were highly correlated to where the violent scattering event took place.

For example, the warm Jupiters were almost all produced by “warm scattering” simulations, where the scattering took place between 0.1 and 1.0 au. The planets that survived the simulations and ended up as warm Jupiters matched all of the properties of the real warm Jupiter population: they had nearby companions, were moderately eccentric, and were mostly aligned with their stars. The hot Jupiters, meanwhile, were almost all produced by “cold scattering” events where the flybys happened far from the star and resulted in one planet hurtling inwards. These also matched all of the observed properties of real hot Jupiters.

The researchers concluded that planet–planet scattering can produce both the warm and hot Jupiter populations so long as you let the planets scatter from a variety of different distances. This exciting theoretical insight, if correct, would mean that astronomers could stop searching for different pathways to create each population. Happily, this model also provides testable predictions, and the authors lay out how the theory could be supported or disproven with additional data. Through virtual experiments like these, astronomers continue to build up an understanding of how the wide range of planetary architectures observed across the galaxy came to be.

By Ben Cassese

Citation
“Unified Formation Channel of Hot and Warm Jupiters via Planet–Planet Scattering,” Julia Esposito et al 2026 ApJL 1003 L3. doi:10.3847/2041-8213/ae61b0


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Friday, May 22, 2026

Astronomers Uncover Why Some Solar Eruptions Die

Full Sun views from different NASA solar cameras of a failed solar eruption from data collected in March 2024.
Credit: Tingyu Gou - - High Resolution Image

Close-up combined views from different NASA solar cameras that each see different temperatures of hot gas (shown in cyan, yellow, and red) of a failed solar eruption from data collected in March 2024. The panels show the same eruption from different angles, as seen on the Sun’s face by the Solar Orbiter spacecraft. Credit: Tingyu Gou


New multi-telescope observations show why a powerful blast never became a true mass ejection.

Cambridge, MA (May, 20, 2026) — A team of scientists has recorded one of the most detailed views ever of a failed solar eruption, a powerful blast from the Sun that never broke free.

In March 2024, the Sun produced an intense solar flare from a large, magnetically complex active region. A prominence, or an ejection of relatively cool, dense gas, rose above the Sun’s surface, carried by the Sun’s twisting magnetic fields that can drive material outward as a coronal mass ejection (CME). Instead, the prominence suddenly slowed, halted, and fell back.

“This strong flare should have produced a big eruption,” said lead author Tingyu Gou, astronomer at the Smithsonian Astrophysical Observatory (SAO), part of the Center for Astrophysics | Harvard & Smithsonian. “Instead, we saw that the eruption stalled and collapsed shortly after its initiation.”

Failed eruptions are not a new discovery; astronomers have observed them, but how and why they occur remains largely a mystery. The team took advantage of a rare observing opportunity to help answer these questions, using data from multiple spacecraft viewing the same event from different angles, and at many wavelengths of light.

NASA’s Solar Dynamics Observatory and the Hinode satellite saw the event from near Earth, while the European Space Agency’s (ESA) Solar Orbiter viewed it from the side. Further radio and ultraviolet observations came from ground-based telescopes and NASA’s IRIS mission.

These combined views, often called multi-messenger observations, allowed the team to track both the hot, X-ray–emitting plasma and the cooler prominence material, and to connect what they saw to a map of the Sun’s underlying magnetic field.

They found that the breaking and rejoining of magnetic field lines was happening at more than one site at the same time. Below the rising magnetic structure, a reconnection of swirling magnetic fields helped push the eruption upward, as is usual in solar flares.

Above it, however, a second reconnection process cut into the top of the erupting magnetic structure itself.

“That upper reconnection weakened the forces that were driving the eruption, which helped to shut it down,” explained Katharine Reeves, astronomer at SAO and coauthor on the paper.

At the same time, very strong overlying magnetic fields acted like a magnetic cage. The scientists’ data showed that these outer fields decayed too slowly to allow the eruption to become unstable and escape. So, the combination of erosion from above and confinement from outside ultimately stopped the eruption in its tracks.

The results help explain a long-standing puzzle in stellar astronomy: why we see many flares on other Sun-like stars, but far fewer clear signs of stellar CMEs. If complex magnetic fields frequently cause eruptions to fail, then some stellar CMEs may die close to the star, and therefore remain hidden from our telescopes, the scientists suggest.

“By watching this failed eruption on our own Sun in detail, we gain a window into how flares and eruptions may work throughout the galaxy,” said Gou. “This work can, in turn, help us understand the physical mechanisms of successful eruptions and space weather environments of distant stars and planets.”

Link to paper: Tingyu Gou, Katharine K. Reeves, Peter R. Young, Astrid M. Veronig, Xingyao Chen, Sijie Yu, Bin Chen & Bin Zhuang (2026) Multi-viewpoint observation of a failed prominence eruption on the Sun, Nature


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Thursday, May 21, 2026

Gravitational-wave detectors can now “autotune” their signals

Artist Impression of astrophysical calibration.
Carl Knox, OzGrav/Swinburne


To the point

  • New method: For the first time, the LIGO-Virgo-KAGRA collaboration has demonstrated a new method to improve the sensitivity of its international network of gravitational-wave detectors.

  • Gravitational-wave auto-tuning: The new method called “astrophysical calibration” resembles auto-tune used in music production. It helps to find and correct “off-key” calibrations of the highly precise laser instruments, which can bias the astrophysical interpretation of the measured signals.

  • Successful demonstration: A new publication in Physical Review Letters successfully demonstrates the method using two loud gravitational-wave signals from binary black hole coalescences.

  • Testing Einstein’s theory: Researchers at the AEI have made crucial contributions to the effort by understanding the interplay between imperfect detector calibration and finding potential deviations from Einstein’s general theory of relativity.


Crucial contributions by AEI researchers: How “off-key” detector calibration can bias signal-based tests of Einstein’s general theory of relativity.

Calibrating the instruments

The LIGO-Virgo-KAGRA (LVK) collaboration’s international network of gravitational-wave detectors consists of five kilometer-sized instruments. All of them reflect ultra-pure laser light back and forth between mirrors to measure the minute length changes – less than a billionth of a billionth of a meter – caused by passing gravitational waves.

To be sensitive to such tiny changes, the detectors must be carefully calibrated in real time. At the heart of this calibration is a precise model of how the detector reacts to gravitational waves. An imperfect detector calibration can compromise how the signal is received and as a consequence also bias the interpretation of the cosmic phenomenon that generated it.


Infographic explaining the astrophysical calibration as autotune for gravitational waves.
Graphics: Shanika Galaudage

Auto-tune for gravitational waves

Now, the LVK reports the first successful demonstration of a new method called “astrophysical calibration” to identify and correct an imperfect detector calibration retrospectively – after the measurement was done. This is similar to how a music production software such as Auto-Tune can correct a singer’s errant pitch after a song was recorded.

If a gravitational-wave signal is observed loud and clear, i.e., when it stands out from the detector’s background noise, the researchers can compare the signal to predictions from general relativity and to observations of the same signal in other well-tuned detectors. This way “off-key” measurements from a mis-tuned detector can be corrected retrospectively. The LVK scientists use the predictions from general relativity to know how the signal should sound like, similar to how musicians use musical scores to know a singer’s pitch.

Two loud gravitational-wave signals

In an article accepted in Physical Review Letters, LVK demonstrate how this technique has been applied to two particularly loud gravitational-wave signals, called GW240925 and GW250207, respectively.

At the times when both these signals were observed – on 25 September 2024 and 7 February 2025, respectively –, the calibration of the LIGO Hanford detector was not optimal. This made the interpretation of its data particularly difficult. By comparing LIGO Hanford data with theoretical predictions and observations of the same signals by the LIGO Livingston detector and the Virgo detector, the researchers were able precisely determine how the “off-key” LIGO Hanford instrument distorted the collected data.

The signal GW240925 served as an acid test for the new method. The astrophysical calibration passed it with flying colors. It confirmed the known calibration errors measured on-site at LIGO Hanford.

In the case of GW250207, however, it was essential to resort to astrophysical calibration to make full use of the data, because no reliable on-site calibration measurements were available for the LIGO Hanford detector. Using the astrophysically corrected calibration for the LIGO Hanford detector, LVK researchers could take calibration uncertainties properly into account, and avoid a biased interpretation of the astrophysical origin of the signal.

In their publication, the LVK astrophysicists report that GW240925 came from a coalescence of two black holes. They weighed 9 and 7 times, respectively, as much as our Sun and their gravitational waves traveled for about 1.0 billion years before reaching the LVK detectors. GW250207 was caused by the coalescence two more massive black holes weighing 35 and 31 times, respectively, as much as our Sun. The waves from this second merger traveled through the Universe for ca. 570 million years before reaching Earth.

Key contributions from AEI Potsdam

Researchers from the Astrophysical and Cosmological Relativity department at the AEI in the Potsdam Science Park showed that taking into account the calibration of the detectors is essential when using gravitational-wave signals for tests of general relativity.

“We found that neglecting imperfect detector calibration can potentially mimic or obscure deviations from Einstein’s theory which may be observed in different parts of black hole coalescence signals,” says Lorenzo Pompili, former member of the department and now a research fellow at the University of Nottingham.

“We used the signal GW250207 to obtain some of the most stringent tests of general relativity yet,” says Elise Sänger, a PhD student in the department. “We got lucky with GW250207, because it was observed so loud and clear and because the Universe gifted us a signal with properties very well suited for these tests.”

“This is the first LVK publication to use an improved waveform model, which we developed at the AEI. Our improvements are important to make increasingly accurate predictions for the gravitational-wave signals, which are key for carrying out these analyses,” says Héctor Estellés Estrella, a former postdoc of the department, now a Postdoctoral Fellow at the Institute of Space Sciences in Barcelona. “The next version of the Gravitational-wave Transient Catalog soon to be published will also make use of this waveform model.”

“We call the phase in which the black hole settles into its final state directly after the merger the ‘ringdown’. In it, the black hole emits a characteristic spectrum of gravitational-wave tones,” explains Elisa Maggio, a former postdoc at AEI Potsdam and now researcher at the Italian Institute for Nuclear Physics. “GW250207 was only the second signal ever in which we constrained one of the higher tones and could measure its properties.”



Media contacts:

Dr. Benjamin Knispel
Press Officer AEI Hannover
Tel: +49 511 762-19104
Email: benjamin.knispel@aei.mpg.de

Dr. Elke Müller
Press Officer AEI Potsdam, Scientific Coordinator
Tel: +49 331 567-7303
Email:elke.mueller@aei.mpg.de


Scientific contacts:

Prof. Dr. Alessandra Buonanno
Director | LSC Principal Investigator
Tel: +49 331 567-7220
Fax: +49 331 567-7298
Email: alessandra.buonanno@aei.mpg.de
Homepage of Alessandra Buonanno

Prof. Dr. Dr. h.c. Karsten Danzmann
Director Emeritus | LSC Principal Investigator
Tel: +49 511 762-2356
Fax: +49 511 762-5861
Email: karsten.danzmann@aei.mpg.de
Homepage of Karsten Danzmann

Dr. Frank Ohme
Research Group Leader | LSC Principal Investigator
Tel: +49 511 762-17171
Fax: +49 511 762-2784
Email: frank.ohme@aei.mpg.de
Homepage of Frank Ohme

Dr. Héctor Estellés
Research Scientist
Email: hestelles@ice.csic.es
Institute of Space Sciences, Barcelona

Dr. Elisa Maggio
INFN Researcher
Email: elisa.maggio@aei.mpg.de
Istituto Nazionale di Fisica Nucleare, Rome

Dr. Lorenzo Pompili
Research Fellow
Email: Lorenzo.Pompili@nottingham.ac.uk
University of Nottingham, School of Mathematical Sciences

Elise Sänger
PhD Student
Email: elise.saenger@aei.mpg.de


Publication

The LIGO Scientific Collaboration; the Virgo Collaboration; the KAGRA Collaboration
GW240925 and GW250207: Astrophysical Calibration of Gravitational-wave Detectors
Physical Review Letters (2026)

Source | DOI

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Wednesday, May 20, 2026

NuSTAR & IXPE coordinated observations of Fairall 51

An artist impression of the obscurer surrounding AGN.
Credit: R. Hurt, NASA/JPL-Caltech
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Joint observations by NuSTAR and NASA’s Imaging X-ray Polarimetry Explorer (IXPE) mission last week offer a unique window into the structure of material around the supermassive black hole at the center of the galaxy Fairall 51. The material near the black hole in this active galactic nucleus (AGN) is thought to be oriented at a peculiar angle that reveals both the black hole’s accretion disk and surrounding circum-polar dust. By combining the unique capabilities of NuSTAR and IXPE, a detailed investigation is being made of the radiation from the hot “corona” near the black hole’s accretion disk as well as X-ray photons reflected by the dust structure beyond the disk. These data will constrain how the corona is oriented relative to the putative “torus” of material around the black hole and the perpendicular polar-scattering region identified by ground-based observatories. Ultimately, this coordinated effort will reveal how the small-scale central engine is physically linked to the vast dust structures around it, providing a full picture of the environment near the accreting supermassive black hole.

Author: Chien-Ting Chen, USRA scientist & IXPE science operations at NASA/MSFC


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Recreating the Cosmos: Modeling Sulfur Chemistry in Interstellar Ice Analogues

Ultraviolet (UV) photons break up molecules in the ice on interstellar dust grains, and subsequent reactivity of the products leads to the synthesis of new molecules. Illustrated here are the starting molecules in the experiment (CS2 and CO2), and assorted sulfur-bearing molecules that either result directly from the break-up of the initial molecules, or are produced via chemical reactions. Disclaimer: This image is an AI-generated creation. © Olli Sipilä


One of astronomy’s most persistent chemical mysteries is why a major part of the sulfur reservoir appears to be missing from dense interstellar clouds. In a new study led by the Center for Astrochemical Studies (CAS) and conducted in collaboration with the Centro de Astrobiología in Madrid, MPE scientists combined laboratory experiments and advanced computer modeling to investigate how sulfur-bearing molecules evolve on icy grains in interstellar space. Their findings suggest that current theories of sulfur chemistry in the cosmos remain incomplete — but also point toward new ways of closing the gap.

Astronomers have long known that sulfur should be far more abundant in dense interstellar clouds than observations indicate. This implies that most of the sulfur reservoir is in a form that is difficult to detect, highly likely residing in the ice covering interstellar dust grains. To shed more light on this “missing sulfur problem”, MPE researchers simulated the irradiation of frozen mixtures of carbon dioxide (CO2) and carbon disulfide (CS2) at temperatures near absolute zero, mimicking conditions inside dark molecular clouds where stars and planets form. Using the pyRate astrochemical code developed at CAS, adapted specifically for the experiment, the team tracked how ultraviolet radiation transforms sulfurbearing ices over time.

The simulations successfully reproduced several key chemical processes seen in the laboratory. But the model also exposed major uncertainties in current understanding of sulfur chemistry. Some compounds — including OCS, CS, and SO — formed too efficiently in the simulations, while others, such as sulfur dioxide and sulfur allotropes, were underproduced. “The discrepancy between the simulations and experiments highlights how limited our knowledge of the evolution of sulfur-bearing compounds under interstellar conditions still is”, says Olli Sipilä, a postdoctoral researcher at MPE who led the study. “However, performing simulations tailored to mimic experiments helps us understand the experimental results better, and also makes it possible to constrain effects that occurred during the experiment but which could not be directly detected.”

Toward Uncovering the Hidden Sulfur Reservoir

Another major finding of the work was that nondiffusive chemistry — chemical reactions occurring without the need for molecules to migrate across the ice surface — is essential for reproducing many of the sulfurbearing compounds observed experimentally. “It is clear that customary models where reactivity is limited by the reactants diffusing on the ice simply cannot reproduce the experimental findings”, says Wiebke Riedel, a postdoctoral researcher and recent CAS graduate who developed the implementation of nondiffusive chemistry in pyRate.

The work represents the first attempt to model a complex, multicomponent interstellar ice experiment using a rate-equation astrochemical code, marking an important milestone for the field. By combining experimental and theoretical approaches, the study offers a new framework for investigating how sulfur is stored and transformed in space — a question closely tied to the chemistry that shapes emerging planetary systems and, ultimately, the ingredients available for life.



Contacts:

Dr. Olli Sipilä
Postdoc at Center for Astrochemical Studies
Tel: +49 89 30000-3646
Email: osipila@mpe.mpg.de
Max-Planck-Institut für extraterrestrische Physik, Garching

Dr. Wiebke Riedel
Postdoc at Center for Astrochemical Studies
Tel: +49 89 30000-3007
Email: riedel@mpe.mpg.de
Max-Planck-Institut für extraterrestrische Physik, Garching


Original Publication

O. Sipilä, R. Martín-Doménech, W. Riedel, D. Navarro-Almaida, A. Fuente, A. Taillard, G.M. Muñoz Caro
Modeling the UV-photon irradiation of CS2-bearing ices in the laboratory with the pyRate gas-grain astrochemical code
Astronomy & Astrophysics

Source | DOI


Further Information


January 23, 2026
Astrophysicists Discover Largest Sulfur-Containing Molecular Compound in Space



July 04, 2024
Using the JWST, a team of researchers including Paola Caselli and Michela Giuliano from MPE, have probed deep into dense cloud cores, revealing details of interstellar ice that were previously unobservable. The study focuses on the Chamaeleon I region, using JWST’s NIRCam to measure spectroscopic lines towards hundreds of stars behind the cloud.

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Tuesday, May 19, 2026

Astronomers Find Most Chemically Primitive Galaxy in Early Universe

Revealing the Nature of the Ultra-Faint Galaxy LAP1-B through a giant “gravitational lens.” A 3 color image created from data taken with the Near-Infrared Camera (NIRCam) on the James Webb Space Telescope (JWST). Because the stars in this galaxy are extremely faint and few in number, the galaxy is invisible in the background image taken by NIRCam, but another instrument, the Near-Infrared Spectrograph (NIRSpec) was able to detect chemical signatures. A visualization (not an actual image) of the NIRSpec velocity and distribution data is shown in the inset for oxygen (green) and two different excitation states of hydrogen (blue and red). (Credit: NASA, ESA, CSA & K. Nakajima et al., Nature). Image (703KB)


An international team of astronomers has used the James Webb Space Telescope (JWST) and a natural phenomenon known as gravitational lensing to achieve a definitive characterization of LAP1-B, an ultra-faint galaxy from 13 billion years ago. Expanding upon initial detections, this new study revealed a record-breaking low oxygen abundance – merely 1/240th that of the Sun. This chemically primitive state, coupled with an elevated carbon-to-oxygen ratio and a dominant dark matter halo, suggests that LAP1-B is the long-sought “ancestor” of the mysterious fossil galaxies found near our Milky Way Galaxy today.

Just after the Big Bang, contained only light elements like hydrogen and helium. The heavier elements, such as oxygen and carbon, were forged much later inside the hearts of the very first stars. For decades, astronomers have tried to find the moment these “first-generation stars” began scattering heavier elements across the cosmos. However, the earliest galaxies hosting such young, primordial stars are so small and faint that seeing their chemical makeup was considered nearly impossible – until now.

A research team led by Kimihiko Nakajima of Kanazawa University and including Masami Ouchi at the National Astronomical Observatory of Japan (NAOJ) and the University of Tokyo focused on a tiny, ultra-faint galaxy named LAP1-B. Its light was magnified 100 times by a phenomenon called “gravitational lensing,” where the gravity of a massive galaxy cluster acts like a natural giant telescope lens in space. By staring at this spot for over 30 hours with JWST, the team determined that the galaxy’s oxygen abundance is roughly 1/240th that of the Sun. “I was instantly thrilled by the extreme lack of oxygen,” says Nakajima. “Finding a galaxy in such a primitive state is astonishing. It’s a chemical signature that clearly indicates a primordial galaxy caught in the moments shortly after its formation.”

Beyond its primitive nature, the galaxy exhibited a high carbon-to-oxygen abundance ratio. This unique ratio of elements aligns closely with theoretical predictions for the material dispersed by the explosions of the universe’s first-generation stars.

The team also discovered that LAP1-B is incredibly lightweight – less than 3,300 times the mass of the Sun – implying that most of the galaxy consists of invisible dark matter. This feature, together with its unique chemical makeup, makes it a near-perfect match for the “Ultra-Faint Dwarf galaxies (UFDs)” found near our Milky Way Galaxy today, which are extremely dim, small, and contain very few stars.

“UFDs are not only the faintest galaxies; they are composed of ancient stars over 12 billion years old and are often described as ‘fossils of the Universe,’” explains Ouchi. “Astronomers suspected they might be the remains of the Universe’s earliest galaxies because they lack heavy elements, but astronomers never had a direct link – until we found LAP1-B.”

Ouchi continues: “It is a profound surprise to find that LAP1-B looks exactly like the ‘ancestor’ we had only imagined in theories. This helps us solve the mystery of why these cosmic fossils have survived in their current form to the present day.”

This discovery establishes a new way to map the birth of elements and the formation of the Universe’s oldest structures. Moving forward, the team will use JWST to search for even more primitive objects, aiming to find the very first galaxies ever formed.



Release Information

Researcher(s) Involved in this Release

Kimihiko Nakajima (Kanazawa University)
Masami Ouchi (National Astronomical Observatory of Japan / University of Tokyo)

Coordinated Release Organization(s)

Kanazawa University
National Astronomical Observatory of Japan, NINS
Institute for Cosmic Ray Research, The University of Tokyo
Paper(s)
K. Nakajima et al. “An ultra-faint, chemically primitive galaxy forming in the reionization era”, in Nature, DOI: 10.1038/s41586-026-10374-1


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Monday, May 18, 2026

Galaxy Cluster Relaxed Now, but was Wild in the Past

Abell 2029
Credit: X-ray: NASA/CXC/CfA/C. Watson et al.; Optical: PanSTARRS;
Image Processing: NASA/CXC/SAO/N. Wolk and P. Edmonds

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A Tour of Abell 2029 - More Videos


  • New data from NASA’s Chandra X-ray Observatory suggests an event-filled past for the galaxy cluster Abell 2029.

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  • The X-rays reveal evidence for a collision with a smaller cluster about four billion years ago.

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  • A sloshing spiral structure was formed when the smaller cluster made its first pass through Abell 2029, pulling its gas sideways.

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  • Galaxy clusters are the largest structures in the Universe held together by gravity and are bellwethers for cosmic growth.


The galaxy cluster Abell 2029 is sometimes described as “the most relaxed cluster in the Universe.” This moniker does not arise from some sort of mellow vibe, but rather because of how calm and undisturbed the superheated gas that pervades the cluster appears to be.

New observations from NASA’s Chandra X-ray Observatory clearly show that Abell 2029 had a much more colorful history than its current disposition suggests. The latest study finds that Abell 2029 is still settling down after a raucous collision with another smaller cluster about four billion years ago.

Galaxy clusters are the largest structures in the Universe held together by gravity. They are made up of hundreds or even thousands of galaxies, unseen dark matter, and a huge amount of gas that fills in the space between the galaxies. This gas is typically heated to millions of degrees, which makes it glow in X-ray light.

A team led by astronomers from Boston University (BU) and the Center for Astrophysics | Harvard & Smithsonian (CfA) obtained the deepest X-ray observation ever made of this cluster using Chandra. The results are described in an Astrophysical Journal paper led by Courtney Watson from BU and CfA.

The Chandra data reveal clear signs that this cluster did not have a mundane history. This new composite image shows evidence for the cluster’s previous shenanigans in the nautilus-like shape in the Chandra data (blue). Optical light from stars and galaxies in the same field of view appears mainly white in an image from Pan-STARRS, a telescope in Hawaii.

The team think the spiral shape in the hot gas formed when gas in the cluster sloshed to the side because of the gravitational effects of the cluster collision — similar to how wine moves in a wine glass. The sloshing spiral in Abell 2029 is one of the longest ever seen, extending about two million light-years from the center of the cluster.

Abell 2029, "splash" and "bay" features labeled. Credit: X-ray: NASA/CXC/CfA/C. Watson et al.; Optical: PanSTARRS; Image Processing: NASA/CXC/SAO/N. Wolk and P. Edmonds

Computer simulations of the collision suggest that the smaller cluster was about ten times less massive than the larger cluster. The sloshing spiral formed when the smaller cluster made its first pass through the larger cluster, pulling its gas sideways. The gravity of the larger cluster then caused the other cluster to slow down and get pulled back in for a second collision. This drove a shock front and left behind a wake of material, forming the splash region.

To uncover these various features the authors used a special technique that examined how much the cluster’s hot gas deviates from a symmetrical shape. Most of the hot gas is symmetrical and is approximately shaped like an oval. The authors removed (“subtracted”) this symmetrical oval shape from the original X-ray image. The remaining X-ray emission in the “subtracted image” clearly shows the unusual features of the sloshing spiral, the bay and the splash area. The shock front is too faint to be seen in this image.

The new composite image combines both the original X-ray and the subtracted X-ray images of the deep Chandra observations of Abell 2029. The subtracted X-ray image (light blue) strikingly shows the sloshing spiral. Most of the original X-ray image is a darker blue color, apart from the center of the image, which is light blue. Two other features — the bay and the splash area — are labeled in an annotated version. The brightness of the original image has been reduced in this image to better show the subtracted image.

Courtney Watson conducted this work as a graduate student at BU and a predoctoral fellow at CfA. In addition to Watson, the authors of the paper are Elizabeth Blanton (Boston University), who was the Principal Investigator for the Chandra observations, Scott Randall (CfA), Tracy Clarke (Naval Research Laboratory), and John ZuHone (CfA).

NASA's Marshall Space Flight Center in Huntsville, Alabama, manages the Chandra program. The Smithsonian Astrophysical Observatory's Chandra X-ray Center controls science operations from Cambridge, Massachusetts, and flight operations from Burlington, Massachusetts.

There are several other key pieces of evidence for the past bash, never before seen together in a cluster, allowing the team to trace the collision history of the cluster in unprecedented detail. For example, the team sees hints of a wide “splash” of cooler gas created by the collision. There may also be a shock wave — akin to a sonic boom from a supersonic plane — in the superheated gas left over from the collision. Finally, there is a “bay” feature in the hot gas, which the researchers think might be caused by an overlap between the outer parts of the spiral and gas stripped away from the smaller cluster as it passed through the larger one. Though the authors think it is a relic from the collision, other explanations for this structure are also possible.




Visual Description:
This release features a composite image of a galaxy cluster with a unique spiral shape, giving it the appearance of a giant galactic seashell floating in the star-speckled blackness of space.

In this composite image, the surrounding stars and individual galaxies appear white, captured in optical light from Pan-STARRS, a telescope in Hawaii. But much of the spiraling cluster is rendered in neon blues, representing X-ray gas observed by Chandra. This super-heated gas fills the space between galaxies, giving the cluster its spiral shape when observed by scientists using an X-ray telescope.

Here, the blue spiral begins as a pale blue dot at the center of the cluster. The spiral stream of light and dark neon blue gas then widens as it moves away from the center of the cluster, gently corkscrewing one full rotation as it extends two-million lightyears into the distance.


Fast Facts for Abell 2029
Credit: X-ray: NASA/CXC/CfA/C. Watson et al.; Optical: PanSTARRS; Image Processing: NASA/CXC/SAO/N. Wolk and P. Edmonds
Release Date: May 12, 2026
Scale: Image is about 25 arcmin (7.2 million light-years) across.
Category: Groups & Clusters of Galaxies
Coordinates (J2000): RA 15h 10m 56.1s | Dec +05° 44´ 40.0"
Constellation: Virgo
Observation Dates: 24 observations from Apr 12, 2000 to Jun 6, 2023
Observation Time: 143 hours 3 minutes (5 days 23 hours 3 minutes)
Obs. ID: 891, 4977, 6101, 25496, 25814-25826, 26380, 26393, 26420, 26428, 27805, 27853, 27848
Instrument: ACIS
References: Watson, C.B., et al., 2026, ApJ, 996, 106.
Color Code: X-ray: blue and white; Optical: red, green, and blue
Distance Estimate: About 1.0 billion light-years from Earth (z~0.0767)

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Sunday, May 17, 2026

Astronomers Directly Detect How Turbulence Between Stars Distorts Light

Radio light from quasar TXS 2005+403 travels roughly 10 billion light-years to reach Earth, traversing the Cygnus region, one of the most turbulent and scattering environments in the Milky Way Galaxy. On the left, this artist's conception shows the quasar as it truly appears, with a bright accretion disk and jets blasting into the galaxy like a beacon through the darkness. On the right, we see how turbulent gas distorts scientists' view of the quasar in much the same way heat haze from a fire warps our view of the objects behind it. In a new study led by astronomers from the Center for Astrophysics | Harvard & Smithsonian (CfA), scientists have for the first time directly detected how interstellar turbulence distorts light from a distant quasar, revealing the structure of that turbulence. Credit: Melissa Weiss/CfA


Using a distant quasar as a beacon, researchers identified the tiny, turbulence-driven ripples imprinted on the quasar’s radio signal as it passed through a particularly chaotic region of the Milky Way.

Cambridge, MA (May 13, 2026) — Astronomers led by the Center for Astrophysics | Harvard & Smithsonian (CfA) have made the first direct detection of turbulence distorting light in the interstellar medium. The findings will help scientists achieve clearer imaging of the supermassive black hole at the center of the Milky Way Galaxy.

The article was published today in The Astrophysical Journal Letters.

The space between stars in our galaxy, known as the interstellar medium, is churning with clouds of ionized gas and electrons. When waves of radio light from distant objects pass through this turbulent material, they are bent and distorted in the same way heat haze rising above a fire distorts our view of everything behind it.

That distortion has long allowed astronomers to infer that the turbulence exists, but understanding its structure has remained out of reach until now.

To measure the turbulence, astronomers set their sights on quasar TXS 2005+403, a bright radio source powered by a supermassive black hole that is located roughly 10 billion light-years away from Earth in the constellation Cygnus. As radio light from the quasar travels toward Earth, it passes through the Cygnus region of the galaxy, one of the most turbulent and strongly scattering environments in the Milky Way, causing the radio waves to be deflected and distorted.

“Most of what we see in the radio data isn’t coming from the quasar itself, it’s coming from the scattering caused by the turbulence in this region of the Milky Way,” said Alexander Plavin, an astronomer at the CfA’s Black Hole Initiative and lead author of the new paper.

“That scattering and the distortions that come with it are what allows us to study the turbulence and better understand and infer its structure.”

To get a better look at the effects of turbulence on light from the quasar, scientists analyzed nearly a decade of archival observations from the U.S. National Science Foundation’s Very Long Baseline Array (NSF VLBA). Operated by NSF’s National Radio Astronomy Observatory (NSF NRAO), the NSF VLBA is a network of ten radio telescopes spread across the country.

Scientists expected that when radio light from TXS 2005+403 passed though the Milky Way, it would spread out into a smooth blur and fade away. Instead, they found persistent, distinct patterns, producing structured, patchy distortions in the light that could only have come from turbulence. “The most distant pairs of telescopes should not have seen the quasar image, but to our surprise, they clearly detected its signal, or faint glow,” Plavin said. “It can’t be explained by simple blurring or by the quasar itself, and it behaves the way turbulence is expected to, which is how we know we’re seeing the effects of interstellar turbulence.”

Plavin added that the scattering properties along this line of sight through the galaxy remain persistent over time.

The findings have significant implications for future astronomical research. The turbulence detected here exists at scales roughly the size of our solar system. Understanding it helps explain how energy moves through the galaxy and how gas behaves before collapsing to form new stars.

The findings may also directly inform efforts to sharpen images of black holes. The Event Horizon Telescope's images of Sagittarius A*, the supermassive black hole at the center of the Milky Way, are degraded by this same interstellar scattering. Studying how turbulence scatters radio light over time and different frequencies provides a path toward removing its effects from those images.

The team has begun a follow-up observing campaign with the NSF VLBA running through 2026, with an aim to measure the specific properties of the screen created by this turbulence and track how it changes as the gas moves relative to Earth.



About the Center for Astrophysics | Harvard & Smithsonian
The Center for Astrophysics | Harvard & Smithsonian is a collaboration between Harvard and the Smithsonian designed to ask, and ultimately answer, humanity's greatest unresolved questions about the nature of the universe. The CfA is headquartered in Cambridge, MA, with research facilities across the U.S. and around the world.

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Saturday, May 16, 2026

A beacon of light in swirls of dust

A spiral galaxy shown in mid-infrared light. The image is dominated by an extremely bright glow from the galaxy’s nucleus. Six large and two smaller rays of light emit from the centre, which are diffraction spikes created by the telescope’s optics. The galaxy’s spiral arms are visible by two lines of glowing orange bubbles which whirl out into the disc. Swirling blue clouds of dust make up the rest of the galaxy. Credit:ESA/Webb, NASA & CSA, A. Leroy


This latest Picture of the Month from the NASA/ESA/CSA James Webb Space Telescope features Messier 77 (M77), a barred spiral galaxy famous and appreciated among astronomers for its combination of relative proximity and spectacular features to study. It is located 45 million light-years away in the constellation Cetus (The Whale). This new image from Webb’s Mid-Infrared Instrument (MIRI) highlights its swirling spiral arms, the dust in its disc and its piercingly bright core like never before.

At the heart of M77 is a compact region filled with hot gas that handily outshines the rest of the galaxy put together, even overcoming the light-gathering capacity of Webb’s cameras. This is an active galactic nucleus (AGN), and it’s powered by M77’s central supermassive black hole, which is eight million times as massive as our Sun. Gas in the galaxy’s central regions is pulled by the strong gravity into a tight and rapid orbit around the black hole, where it crashes together and heats up, releasing tremendous amounts of radiation.

The bright orange lines appearing to radiate out from the centre of M77 are not actually a feature of the galaxy: they are a type of distortion that arises from the optical design of the telescope. Called diffraction spikes, they are created because the intense light from the unresolved AGN is bent (“diffracted”) very slightly at the edges of Webb’s hexagonal mirror panels and around one of the struts that hold up its secondary mirror. This distinctive six-plus-two-pointed pattern is the same for any image taken by Webb. For diffraction spikes to appear, the light source has to be very bright and very concentrated, so they’re most often seen on stars. But in some galaxies, as here, the nucleus is bright and compact enough to make diffraction spikes appear as well.

M77 is not just known for its easily visible AGN, but also as a prolific star-forming galaxy. The near-infrared image of M77 reveals a bar spanning across the central region, which doesn’t appear in visible-light images of the galaxy. The bar is enclosed by a bright ring, called a starburst ring, formed by the inner ends of M77’s two spiral arms. Starburst regions in galaxies are typified by extremely high star-formation rates. This ring is more than 6 000 light-years across and displays intense and widespread starbursts, visible in this image by the densely concentrated orange bubbles all around the ring. Since M77 is relatively close to Earth, this starburst ring is a very well-studied example of the phenomenon.

As an active spiral galaxy, M77’s disc is filled with gas and dust which is both a product of and fuel for future star formation. Webb’s MIRI fills out our view of the galaxy with the glow of interstellar dust grains emitted at longer wavelengths, shown here in blue. The dust forms a huge vortex of smoky, swirling filaments with cavities in between. The glowing orange bubbles carved out by newly formed star clusters are also prominently visible out along the galaxy’s arms.

Beyond Webb’s quite focused view, M77’s arms join into a faint extended ring of hydrogen gas thousands of light-years wide, where yet more star formation is taking place. Vast, tenuous filaments of hydrogen gas stretch across this ring and out into intergalactic space, forming an outermost layer around the galaxy. For the tentacle-like appearance of these filaments, M77 is also named the Squid Galaxy.

The data used to create this image are from an observing programme (#3707) that surveyed massive, nearby, star-forming galaxies to create a rich dataset useful for many scientific investigations. As can be seen here, the stunning resolution of Webb’s instruments reveals star clusters and rich reservoirs of gas, which can be used to explore the cycle of star formation, life and death in these and other galaxies.



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