Tuesday, April 30, 2024

Orion's Erupting Star System Reveals Its Secrets

Artist's impression of the large-scale view of FU~Ori. The image shows the outflows produced by the interaction between strong stellar winds powered by the outburst and the remnant envelope from which the star formed. The stellar wind drives a strong shock into the envelope, and the CO gas swept up by the shock is what the new ALMA revealed. Image credit: NSF/NRAO/S. Dagnello
. Hi-res image

Zoom into the FU Ori binary system and the newly discovered accretion streamer. This artist's impression shows the newly discovered streamer constantly feeding mass from the envelope into the binary system. Image credit: NSF/NRAO/S. Dagnello
. Hi-res image



ALMA sheds light on 88-year-old astronomical mystery

An unusual group of stars in the Orion constellation have revealed their secrets. FU Orionis, a double star system, first caught astronomers' attention in 1936 when the central star suddenly became 1,000 times brighter than usual. This behavior, expected from dying stars, had never been seen in a young star like FU Orionis. The strange phenomenon inspired a new classification of stars sharing the same name (FUor stars). FUor stars flare suddenly, erupting in brightness, before dimming again many years later. It is now understood that this brightening is due to the stars taking in energy from their surroundings via gravitational accretion, the main force that shapes stars and planets. However, how and why this happens remained a mystery—until now, thanks to astronomers using the Atacama Large Millimeter/submillimeter Array (ALMA).

"FU Ori has been devouring material for almost 100 years to keep its eruption going. We have finally found an answer to how these young outbursting stars replenish their mass," explains Antonio Hales, Deputy Manager of the North American ALMA Regional Center, a scientist with the National Radio Astronomy Observatory, and lead author of this research, published today in the Astrophysical Journal, "For the first time we have direct observational evidence of the material fueling the eruptions."

ALMA observations revealed a long, thin stream of carbon monoxide falling onto FU Orionis. This gas didn't appear to have enough fuel to sustain the current outburst. Instead, this accretion streamer is believed to be a leftover from a previous, much more significant feature that fell into this young stellar system. "It is possible that the interaction with a bigger stream of gas in the past caused the system to become unstable and trigger the brightness increase," explains Hales.

Astronomers used several configurations of ALMA antennas to capture the different types of emission coming from FU Orionis and detect the mass flow into the star system. They also combined novel numerical methods to model the mass flow as an accretion streamer and estimate its properties. "We compared the shape and speed of the observed structure to that expected from a trail of infalling gas, and the numbers made sense," says Aashish Gupta, a Ph.D. candidate at European Southern Observatory (ESO) and a co-author of this work, who developed the methods used to model the accretion streamer.

"The range of angular scales we can explore with a single instrument is remarkable. ALMA gives us a comprehensive view of the dynamics of star and planet formation, spanning from large molecular clouds in which hundreds of stars are born, down to the more familiar scales of solar systems," adds Sebastián Pérez of Universidad de Santiago de Chile (USACH), director of the Millennium Nucleus on Young Exoplanets and their Moons (YEMS) in Chile, and co-author of this research.

These observations also revealed an outflow of slow-moving carbon monoxide from FU Orionis. This gas is not associated with the most recent outburst. Instead, it is similar to outflows observed around other protostellar objects. Adds Hales, “By understanding how these peculiar FUor stars are made, we’re confirming what we know about how different stars and planets form. We believe that all stars undergo outburst events. These outbursts are important because they affect the chemical composition of the accretion discs around nascent stars and the planets they eventually form.”

“We have been studying FU Orionis since ALMA's first observations in 2012,” adds Hales. It’s fascinating to finally have answers.”




Additional Information

This research was published in an article titled "Discovery of an accretion streamer and a slow wide-angle outflow around FU Orionis" by A. Hales et al. in the Astrophysical Journal.

The Atacama Large Millimeter/submillimeter Array (ALMA), an international astronomy facility, is a partnership of ESO, the U.S. National Science Foundation (NSF) and the National Institutes of Natural Sciences (NINS) of Japan in cooperation with the Republic of Chile. ALMA is funded by ESO on behalf of its Member States, by NSF in cooperation with the National Research Council of Canada (NRC) and the National Science and Technology Council (NSTC) in Taiwan and by NINS in cooperation with the Academia Sinica (AS) in Taiwan and the Korea Astronomy and Space Science Institute (KASI).

ALMA construction and operations are led by ESO on behalf of its Member States; by the National Radio Astronomy Observatory (NRAO), managed by Associated Universities, Inc. (AUI), on behalf of North America; and by the National Astronomical Observatory of Japan (NAOJ) on behalf of East Asia. The Joint ALMA Observatory (JAO) provides the unified leadership and management of the construction, commissioning and operation of ALMA.



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Bárbara Ferreira
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Phone:
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Email: press@eso.org


Monday, April 29, 2024

Webb Captures Top of Iconic Horsehead Nebula in Unprecedented Detail

Horsehead Nebula (NIRCam Image)
Credits: Image: NASA, ESA, CSA, Karl Misselt (University of Arizona), Alain Abergel (AIM Paris-Saclay)


Horsehead Nebula (MIRI Image)
Credits: Image: NASA, ESA, CSA, Karl Misselt (University of Arizona), Alain Abergel (AIM Paris-Saclay)


Horsehead Nebula (Euclid, Hubble and Webb images)
Credits: Image: NASA, ESA, CSA, Karl Misselt (University of Arizona), Alain Abergel (AIM Paris-Saclay), Mahdi Zamani The Euclid Consortium, Hubble Heritage Project (STScI, AURA)




A clumpy dome of blueish-gray clouds topped with streaky, translucent red wisps. A large, prominent star is at the top of the image.

NASA’s James Webb Space Telescope has captured the sharpest infrared images to date of a zoomed-in portion of one of the most distinctive objects in our skies, the Horsehead Nebula. These observations show the top of the "horse's mane" or edge of this iconic nebula in a whole new light, capturing the region’s complexity with unprecedented spatial resolution.

Webb’s new images show part of the sky in the constellation Orion (The Hunter), in the western side of a dense region known as the Orion B molecular cloud. Rising from turbulent waves of dust and gas is the Horsehead Nebula, otherwise known as Barnard 33, which resides roughly 1,300 light-years away.

The nebula formed from a collapsing interstellar cloud of material, and glows because it is illuminated by a nearby hot star. The gas clouds surrounding the Horsehead have already dissipated, but the jutting pillar is made of thick clumps of material and therefore is harder to erode. Astronomers estimate that the Horsehead has about five million years left before it too disintegrates. Webb’s new view focuses on the illuminated edge of the top of the nebula’s distinctive dust and gas structure.

The Horsehead Nebula is a well-known photodissociation region, or PDR. In such a region, ultraviolet (UV) light from young, massive stars creates a mostly neutral, warm area of gas and dust between the fully ionized gas surrounding the massive stars and the clouds in which they are born. This UV radiation strongly influences the chemistry of these regions and acts as a significant source of heat.

These regions occur where interstellar gas is dense enough to remain mostly neutral, but not dense enough to prevent the penetration of UV light from massive stars. The light emitted from such PDRs provides a unique tool to study the physical and chemical processes that drive the evolution of interstellar matter in our galaxy, and throughout the universe from the early era of vigorous star formation to the present day.

Due to its proximity and its nearly edge-on geometry, the Horsehead Nebula is an ideal target for astronomers to study the physical structures of PDRs and the molecular evolution of the gas and dust within their respective environments, and the transition regions between them. It is considered one of the best regions in the sky to study how radiation interacts with interstellar matter.

Thanks to Webb’s MIRI and NIRCam instruments, an international team of astronomers has revealed for the first time the small-scale structures of the illuminated edge of the Horsehead. As UV light evaporates the dust cloud, dust particles are swept out away from the cloud, carried with the heated gas. Webb has detected a network of thin features tracing this movement. The observations have also allowed astronomers to investigate how the dust blocks and emits light, and to better understand the multidimensional shape of the nebula.

Next, astronomers intend to study the spectroscopic data that have been obtained to gain insights into the evolution of the physical and chemical properties of the material observed across the nebula.

These observations were taken for the Webb GTO program 1192 and the results were published today in Astronomy & Astrophysics.

The James Webb Space Telescope is the world's premier space science observatory. Webb is solving mysteries in our solar system, looking beyond to distant worlds around other stars, and probing the mysterious structures and origins of our universe and our place in it. Webb is an international program led by NASA with its partners, ESA (European Space Agency) and the Canadian Space Agency.




About This Release

Credits:

Media Contact:

Bethany Downer
ESA/Webb, Baltimore, Maryland

Christine Pulliam
Space Telescope Science Institute, Baltimore, Maryland

Permissions: Content Use Policy

Contact Us: Direct inquiries to the News Team.

Related Links and Documents


Sunday, April 28, 2024

Radio telescope becomes stellar ‘speed camera’ in deep-space experiment


Matter spirals into a neutron star from a nearby companion, boosting the jets from the top and bottom of the neutron star as it does. Credit: ESA

In a world first, researchers have measured the jets of neutron stars to be moving at 114,000km per second – one-third the speed of light.

The international team achieved this result using the European Space Agency (ESA)’s orbiting gamma ray telescope, Integral, and the Australia Telescope Compact Array (ATCA) on Gomeroi Country which is owned and operated by Australia’s national science agency, CSIRO.

Neutron stars, like black holes, have huge gravitational pulls. When pulling matter from a nearby star, their extreme environments cause the occasional thermonuclear explosion and constant jets of matter shooting into space. Not much is known about these jets, including their composition and speed.

These latest results, published today in Nature, revealed that thermonuclear explosions – detected by Integral – pushed gas into the jets. The jets were then tracked with ATCA allowing their speed to be recorded.

Professor James Miller-Jones from the Curtin University node of the International Centre for Radio Astronomy Research (ICRAR) was one of the project researchers.

He said it’s typically hard to measure the speed of a jet, but discovering the jets are enhanced after every thermonuclear explosion provides a new way of measuring their speeds.

“The explosion tells us when the enhanced jets were launched, and we simply time them as they move downstream – just like we would time a 100m sprinter as they move between the starting blocks and the finish line,” Professor Miller-Jones said.


CSIRO’s Dr Jamie Stevens, who leads the ATCA operations team in Narrabri, describes the telescope as a world-class and adaptable instrument.

“Radio telescopes are extremely versatile in the research they can do,” Dr Stevens said.

“The sensitivity and stability of ATCA allowed this research team to observe rapid changes in the neutron star’s surroundings over three days.

“This new method will help astronomers to better understand jets in many different environments and the complex events that build our Universe,” he said.




Publication

Russell, Degenaar, van den Eijnden et al, ‘Thermonuclear explosions on neutron stars reveal the speed of their jets, Nature, 27 March 2024, DOI 10.1038/s41586-024-07133-5



Saturday, April 27, 2024

Mysterious object in the gap

Inspiral of a lower mass-gap black hole (dark gray surface) and a neutron star (orange sphere). The emitted gravitational waves are shown in colors from dark blue to cyan. © I. Markin (Potsdam University), T. Dietrich (Potsdam University and Max Planck Institute for Gravitational Physics), H. Pfeiffer, A. Buonanno (Max Planck Institute for Gravitational Physics)

Shortly after the start of the fourth observing run, the LIGO-Virgo-KAGRA collaborations detected a remarkable gravitational-wave signal.

The LIGO Livingston detector observed the signal, called GW230529, on May 29, 2023, from the merger of a neutron star with an unknown compact object, most likely an unusually light-weight black hole. With a mass of only a few times that of our Sun, the object falls into the “lower mass gap” between the heaviest neutron stars and the lightest black holes. Researchers at the Max Planck Institute for Gravitational Physics contributed to the discovery with accurate waveform models, new data-analysis methods, and sophisticated detector technology. Although this particular event was observed only because of its gravitational waves, it increases the expectation that more such events will also be observed with electromagnetic waves in the future.

The lower mass gap

For about 30 years, researchers have debated whether there is a mass gap separating the heaviest neutron stars from the lightest black holes. Now, for the first time, LVK scientists have found an object whose mass falls right into this gap, which was thought to be almost empty. “These are very exciting times for gravitational-wave research as we delve into realms that promise to reshape our theoretical understanding of astrophysical phenomena dominated by gravity,” says Alessandra Buonanno, Director at the Max Planck Institute for Gravitational Physics in Potsdam Science Park.

Einstein's theory of general relativity predicts neutron stars to be lighter than three times the mass of our Sun. However, the exact value of the maximum mass that a neutron star can have before collapsing into a black hole is unknown. “Considering electromagnetic observations and our present grasp of stellar evolution, there were expected to be very few black holes or neutron stars within the range of three to five solar masses. However, the mass of one of the newly discovered objects precisely aligns with this range,” Buonanno elaborates.

In recent years, astronomers have uncovered several objects whose masses potentially fit within this elusive gap. In the case of GW190814, LIGO and Virgo identified an object at the lower boundary of the mass spectrum. However, the compact object detected via the gravitational-wave signal GW230529 marks the first instance where its mass unequivocally falls within this gap.

New observing run with more sensitive detectors and improved search methods

The highly successful third observing run of the gravitational-wave detectors ended in spring 2020, bringing the number of known gravitational-wave events to 90. Before the start of the fourth observing run O4 on May 24, 2023, the LVK researchers made several improvements to the detectors to increase their sensitivity. “Researchers at the Max Planck Institute for Gravitational Physics (Albert Einstein Institute/AEI) in Hannover, together with LIGO colleagues, have improved the laser sources of the LIGO detectors at the heart of the instruments,” explains Karsten Danzmann, Director at AEI and Director of the Institute for Gravitational Physics at Leibniz University Hannover. “They provide high-precision laser light with an output power of up to 125 watts, with the same characteristics over very short and very long time scales.” Benno Willke, leader of the laser development group at AEI Hannover, adds: “The reliability and performance of the new solid-state laser amplifiers is amazing and I'm convinced that they will still be used in the next detector upgrade.”

But not only the hardware has been improved: the new observing run took advantage of an efficient waveform code infrastructure, and the accuracy, speed, and physical content of the waveform models developed at the AEI Potsdam were improved, so that black-hole properties can be extracted in a few days.

O4 starts with a bang

Just five days after the launch of O4, things got really exciting: on May 29, 2023, the LIGO Livingston detector observed a gravitational wave that was published within minutes as signal candidate “S230529ay”. The result of this “online analysis”, which was performed almost in real time as the signal arrived, was that a neutron star and a black hole most likely merged about 650 million light-years from Earth. However, it is not possible to say exactly where the merger took place because only one gravitational-wave detector was recording scientific data at the time of the signal. Therefore, the direction from which the gravitational waves came could not be determined.

The LVK researchers made sure that the signal was not a local disturbance in the LIGO Livingston detector, but actually came from deep space. “Among other things, we examined all the perturbations and random fluctuations of detector noise that resemble weak signals,” explains Frank Ohme, leader of a Max Planck research group at AEI Hannover. “GW230529 clearly stands out from this background and was consistently detected by several independent search methods. This clearly indicates an astrophysical origin of the signal.”

The astrophysicists also used GW230529 to test Einstein's general theory of relativity. “GW230529 is in perfect agreement with the predictions of Einstein's theory,” says Elise Sänger, a graduate student at AEI Potsdam who was involved in the study. “It provided some of the best constraints to date on alternative theories of gravity using LVK gravitational-wave events.”

GW230529: Neutron star meets unknown compact object

To determine the properties of the objects that orbited each other and merged, producing the gravitational-wave signal, astronomers compared data from the LIGO Livingston detector with two state-of-the art waveform models. “The models incorporate a range of relativistic effects to ensure the resulting signal model is as realistic and comprehensive as possible, facilitating comparison with observational data,” says Héctor Estellés Estrella, a postdoctoral researcher in the team AEI Potsdam team who developed one of the models. “Among other things, our waveform model can accurately describe black holes swirling around in space-time at a fraction of the speed of light, emitting gravitational radiation across multiple harmonics,” adds Lorenzo Pompili, a PhD student at the AEI Potsdam who also built the model.

Numerical simulation of the compact binary system GW230529: Matter and waves
© I. Markin (Potsdam University), T. Dietrich (Potsdam University and Max Planck Institute for Gravitational Physics), H. Pfeiffer, A. Buonanno (Max Planck Institute for Gravitational Physics)

GW230529 was formed by the merger of a compact object with 1.3 to 2.1 times the mass of our Sun with another compact object with 2.6 to 4.7 times the solar mass. Whether these compact objects are neutron stars or black holes cannot be determined with certainty from gravitational-wave analysis alone. However, based on all the known properties of the binary, LVK astronomers believe that the lighter object is a neutron star and the heavier is a black hole.

The mass of the heavier object therefore lies confidently in the mass gap, which was previously thought to be mostly empty. None of the previous candidates for objects in this mass range have been identified with the same certainty.

Scientists expect more observations of similar signals

Of all the neutron star-black hole mergers observed to date, GW230529 is the one in which the masses of the two objects are the least different. Tim Dietrich, a professor at the University of Potsdam and leader of a Max Planck Fellow group at the AEI, explains: “If the black hole is significantly heavier than the neutron star, no matter is left outside the black hole after the merger, and no electromagnetic radiation is emitted. Lighter black holes, on the other hand, can rip apart the neutron star with their stronger tidal forces, ejecting matter that can glow as a kilonova or a gamma-ray burst”.

The observation of such an unusual system shortly after the start of the O4 run also suggests that further observations of similar signals can be expected. The LVK researchers have calculated how often such pairs merge and found that these events occur at least as often as the previously observed mergers of neutron stars with heavier black holes. Therefore, an afterglow in the electromagnetic spectrum should be observed more frequently than previously thought.

A mysterious compact object

LVK scientists can only make an educated guess as to how the heavier of the compact objects – most likely a lightweight black hole – in the binary that emitted GW230529 was formed. It is too light to be the direct product of a supernova. It is possible – but unlikely – that it was formed during a supernova, where material initially ejected in the explosion falls back and causes the newly formed black hole to grow. It is even less likely that the black hole was formed in the merger of two neutron stars. An origin as a primordial black hole in the early days of the universe is also possible, but not very likely. Finally, the researchers cannot completely rule out the possibility that the heavier object is not a light black hole, but an extremely heavy neutron star.

The fourth observing run continues

So far, a total of 81 significant signal candidates have been identified in O4a, the first half of the fourth observing run. GW230529 is the first of these that has now been published after detailed investigation.

After a commissioning break of several weeks and a subsequent engineering run, O4b, the second half of O4, begins on April 10. Both LIGO detectors, Virgo, and GEO600, will participate in O4b.

While the observing run continues, LVK researchers are analyzing the observational data from O4a and checking the remaining 80 significant signal candidates that have already been identified. The sensitivity of the detectors should be slightly increased after the break. By the end of the fourth observing run in February 2025, a similar number of new candidates are expected to be added, and the total number of observed gravitational-wave signals will soon exceed 200.




Gravitational-wave observatories

LIGO is funded by the NSF, and operated by Caltech and MIT, which conceived and built the project. Financial support for the Advanced LIGO project was led by NSF with Germany (Max Planck Society), the U.K. (Science and Technology Facilities Council) and Australia (Australian Research Council) making significant commitments and contributions to the project. More than 1,600 scientists from around the world participate in the effort through the LIGO Scientific Collaboration, which includes the GEO Collaboration. Additional partners are listed at https://my.ligo.org/census.php.

The Virgo Collaboration is currently composed of approximately 880 members from 152 institutions in 17 different (mainly European) countries. The European Gravitational Observatory (EGO) hosts the Virgo detector near Pisa in Italy, and is funded by Centre National de la Recherche Scientifique (CNRS) in France, the Istituto Nazionale di Fisica Nucleare (INFN) in Italy, and the National Institute for Subatomic Physics (Nikhef) in the Netherlands. A list of the Virgo Collaboration groups can be found at: https://www.virgo-gw.eu/about/scientific-collaboration/. More information is available on the Virgo website at https://www.virgo-gw.eu.

KAGRA is the laser interferometer with 3 km arm-length in Kamioka, Gifu, Japan. The host institute is Institute for Cosmic Ray Research (ICRR), the University of Tokyo, and the project is co-hosted by National Astronomical Observatory of Japan (NAOJ) and High Energy Accelerator Research Organization (KEK). KAGRA collaboration is composed of over 400 members from 128 institutes in 17 countries/regions. KAGRA’s information for general audiences is at the website https://gwcenter.icrr.u-tokyo.ac.jp/en/. Resources for researchers are accessible from http://gwwiki.icrr.u-tokyo.ac.jp/JGWwiki/KAGRA.



Media contacts:

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

Dr. Elke Müller
Press Officer AEI Potsdam, Scientific Coordinator
+49 331 567-7303
+49 331 567-7298 (Fax)
elke.mueller@aei.mpg.de



Scientific contacts:

Prof. Dr. Alessandra Buonanno
+49 331 567-7220
+49 331 567-7298 (Fax)
alessandra.buonanno@aei.mpg.de
Homepage of Alessandra Buonanno

Prof. Dr. Karsten Danzmann
Director | LSC Principal Investigator

+49 511 762-2356
+49 511 762-5861 (Fax)
karsten.danzmann@aei.mpg.de

Homepage of Karsten Danzmann

Dr. Frank Ohme
Research Group Leader | LSC Principal Investigator

+49 511 762-17171
+49 511 762-2784 (Fax)

frank.ohme@aei.mpg.de
Homepage of Frank Ohme

Prof. Dr. Tim Dietrich
Max Planck Fellow
+49 331 567-7253
+49 331 567-7298 (Fax)
tim.dietrich@aei.mpg.de

Dr. Héctor Estellés Estrella
Junior Scientist/Postdoc
+49 331 567-7193
hector.estelles@aei.mpg.de

Lorenzo Pompili
PhD Student
+49 331 567-7182
+49 331 567-7298 (Fax)
lorenzo.pompili@aei.mpg.de

Elise Sänger
PhD Student
+49 331 567-7183
elise.saenger@aei.mpg.de

Apl. Prof. Dr. Benno Willke
Research Group Leader
+49 511 762-2360
benno.willke@aei.mpg.de



Publication

The LIGO Scientific Collaboration, the Virgo Collaboration, and the KAGRA Collaboration
Observation of Gravitational Waves from the Coalescence of a 2.5–4.5 M
Compact Object and a Neutron Star


Source




Further information

Current gravitational-wave astronomy Up-to-date information on gravitational-wave astronomy and expertise at the Max Planck Institute for Gravitational Physics in Hannover and Potsdam.

more

LIGO news item
about GW230529


Friday, April 26, 2024

Jupiter's Rings


Jupiter’s ring wasn’t discovered until Voyager 1 visited the planet in 1979. Not only is it thin and faint, scattered light from the bright planet Jupiter washes out the ring. It is virtually impossible for even the best Earth based telescopes to see Jupiter’s ring. But the NAOJ’s Subaru Telescope was able to overcome those difficulties to take this picture.

The red glow around Jupiter is light from the planet scattered by Earth’s atmosphere and the instrument optics. The red lines in the lower-right of the picture are images of Jupiter’s moon Thebe (J XIV). It moved during the 13 minutes required to take this picture, so it blurred and stretched out.

Unlike Saturn’s ring which is composed primarily of water-ice particles, Jupiter’s ring is made of dust. This observation used a special filter to observe water-ice. That data is represented by blue in this false-color infrared image. As you can see there is almost no blue in the ring.

Astronomers believe that Saturn’s ring was made when comets, asteroids, or now vanished moons came too close to the planet and were ripped apart by Saturn’s strong gravity. In contrast, the dust in Jupiter’s ring seems to be coming from micro-meteor impacts throwing out material from the surfaces of Jupiter’s moons.

Author: Ramsey Lundock




Download: Maximum resolution (751 x 716, 95KB)

Related Links: Subaru Telescope



Image Data

Observation Date: May25, 2005
Telescope: The Subaru Telescope (Effective Diameter 8.2 m), Cassegrain Focus
Wavelengths (Filters): K’ (2.20µm), H2O Ice (3.05µm), L (3.77µm)
Color Code: Blue (H2O Ice), Green (L), Red (K’)
Instrument: IRCS (Infrared Camera and Spectrograph)
Exposure Time: 270s & 300s (K’), 200s (H2O Ice), 60s (L)
Location: Mauna Kea, Hawai’i Island
Observers: Takato & Terada
Image Processing: Ramsey Lundock
Object Name: Jupiter
Image Size: cropped to approximately 43 arcseconds
Copyright: National Astronomical Observatory of Japan


Thursday, April 25, 2024

Travel Through Data From Space in New 3D Instagram Experiences

Vela Pulsar - Tycho's Supernova Remnant - Helix Nebula - Cat's Eye Nebula
Credit: Vela Pulsar: X-ray: NASA/CXC/SAO; Optical: NASA/ESA/STScI; Image processing: NASA/CXC/SAO/J. Schmidt, K. Arcand; Tycho's Supernova Remnant: X-ray: NASA/CXC/SAO; Optical: DSS; Image Processing: NASA/CXC/SAO/N. Wolk; Helix Nebula: X-ray: NASA/CXC/SAO; UV: NASA/JPL-Caltech/SSC; Optical: NASA/ STScI/M. Meixner, ESA/NRAO/T.A. Rector; Infrared:NASA/JPL-Caltech/K. Su; Image Processing: NASA/CXC/SAO/N. Wolk and K. Arcand; Cat's Eye Nebula: X-ray: NASA/CXC/SAO; Optical: NASA/ESA/STScI; Image Processing: NASA/CXC/SAO/J. Major, L. Frattare, K. Arcand





These images represent new special 3D “experiences” available on Instagram made with data from NASA’s Chandra X-ray Observatory and other telescopes. By using augmented reality (AR), these experiences allow people to travel virtually through objects in space.

These Chandra Instagram experiences join a space-themed collection in Instagram from recent years, that includes NASA mission control, the International Space Station, and the Perseverance Rover on Mars. The objects in the new Chandra Instagram collection include the Tycho supernova remnant, the Vela Pulsar, the Helix Nebula, the Cat’s Eye, and the Chandra spacecraft.

The new Instagram experiences are created from 3D models based on data collected by Chandra and other telescopes along with computer models. Traditionally, it has been very difficult to gather 3D data of objects in space due to their two-dimensional projection on the sky. New instruments and techniques, however, have allowed astronomers in recent years to construct data-driven models of what these distant objects look like in three dimensions.

These advancements in astronomy have paralleled the explosion of opportunities in virtual, extended, and augmented reality. Such technologies provide virtual digital experiences, which now extend beyond Earth and into the cosmos.


Tycho's Supernova Remnant Effect [More Effects]
Video Credit: Smithsonian/NASA/SAO/CXC;
Sonification: NASA/CXC/SAO/K.Arcand, SYSTEM Sounds (M. Russo, A. Santaguida)

This new set of Chandra Instagram experiences was made possible by a collaboration including NASA and the Smithsonian Institution, as well as students and researchers at Brown University. The 3D models of Tycho, Vela and Helix were done in conjunction with Sal Orlando, an astrophysicist at Italy’s National Institute for Astrophysics in Palermo. The Cat’s Eye Nebula was created with data from Ryan Clairmont, physics researcher and undergraduate at Stanford University. Kim Arcand from SAO oversaw the project and worked with Brown University’s Tom Sgouros and his team, research assistant Alexander Dupuis and undergraduate Healey Koch, on the Chandra Instagram filters.




Vela Pulsar

Vela Pulsar: The Vela Pulsar is the aftermath of a star that collapsed, followed by an explosion that sent a remarkable storm of particles and energy into space. The Chandra X-ray Observatory and other telescopes captured this storm, seen here as a 3D model. At the center of Vela is a pulsar, a rapidly spinning dense star that sends beams of light out into space like a cosmic lighthouse.

Tycho's Supernova Remnant

Tycho's Supernova Remnant: Massive stars die in giant explosions called supernovas that can outshine an entire galaxy. After a supernova explosion, the remains of the star can become a spectacular and evolving cosmic monument to the now-deceased star. These remnants glow in X-ray light, which NASA’s Chandra X-ray Observatory can detect such as in this image of Tycho’s Supernova Remnant.

Helix Nebula

Helix Nebula:In about 5 billion years, our Sun will run out of fuel and expand, possibly engulfing Earth. These end stages of a star’s life can be utterly beautiful as is the case with this planetary nebula called the Helix Nebula. Astronomers study these objects by looking at all kinds of light, including X-rays that the Chandra X-ray Observatory sees.

Cat's Eye Nebula

Cat's Eye Nebula:Eventually, our Sun will run out of fuel and die (though not for about another 5 billion years). As it does, it will become like the object seen here, the Cat’s Eye Nebula, which is a planetary nebula. A fast wind from the remaining stellar core rams into the ejected atmosphere and pushes it outward, creating wispy structures seen in X-rays by Chandra and optical light by the Hubble Space Telescope.

Chandra Spacecraft

Chandra Spacecraft: A quarter of a century ago, scientists began a quest to answer some of the biggest questions in the Universe. They have discovered many truths — and uncovered even more mysteries. Since it was launched into space in July 1999, NASA’s Chandra X-ray Observatory has changed our view of the Universe. With this telescope, we continue to see what is otherwise invisible. We are still learning, exploring, and expanding humanity’s grasp of what the Universe has to offer. Our X-ray legacy continues.



Visual Description:

This image contains four separate images presented in a 2 by 2 grid. Top left, Vela pulsar. Top right, Tycho's Supernova Remnant. Bottom left, Helix Nebula. Bottom right, Cat's Eye Nebula.

The Vela Pulsar, the aftermath of a collapsed and exploded star sending a jet of particles into space. The pulsar resembles a soft, pillowy, lavender bean in a pocket of blue gas. A faint stream of gas, the X-ray jet, appears to shoot from the pocket, heading into the distance at our upper right. Purple markings in the lavender bean shape strongly resemble narrow eyes and an open mouth, giving the pulsar a squinting happy face. In this image, X-ray light detected by Chandra is shown in blues and purples.

The Tycho supernova remnant is a spherical cloud of reds, greens, and blues set against a starry sky. The cloud is ejected material still propagating from a star that exploded in 1572, as seen from Earth. Here, the supernova resembles a fluffy pink cotton ball. The dense, translucent cloud is streaked with hazy veins, and mottled with red and blue. The edges of the cloud appear to be highlighted in soft white. Upon close inspection, a thin red-violet line can be discerned around the outer edge of the multicolored cloud. The red-violet line shows where electrons have been accelerated to high energies, producing X-rays detected by Chandra. This provides evidence that supernova remnants are a major source of energetic particles, including electrons and protons, which continually hit Earth's atmosphere.

The Helix Nebula is a planetary nebula, the end phases of the life of a Sun-like star. Helix resembles a creature's eye, both in shape and in detail. At the center of the nebula, where the pupil would reside, an orb shaped cloud glows in dark pink. Surrounding the orb, where the colored iris of an eye would be, is a dramatic mix of color in blues, browns, and golds that appear somewhat striated, very similar to a human eye. These striations extend to the left and right of the otherwise circular iris structure, as though they had been gently pulled from the two o'clock and seven o'clock positions until the material formed faint wisps. Surrounding the iris structure are roughly spherical puffs of blue haze. The entire canvas is dotted with stars in red, green, and blue.

The Cat's Eye Nebula is an image of an ethereal shape surrounded by concentric circles. The shape is a huge cloud of gas and dust blown off of a dying star. The concentric circles are bubbles expelled by the star over time. The dust cloud resembles a translucent pastry pulled to golden yellow points near our upper right and lower left, with a blob of bright purple jelly inside the bulbous pale blue core. The jelly-like center represents X-ray data from Chandra. The outer cloud and translucent circles represent visible light data from the Hubble Space Telescope.



Fast Facts for Vela Pulsar:

Credit: X-ray: NASA/CXC/SAO; Optical: NASA/ESA/STScI; Image processing: NASA/CXC/SAO/J. Schmidt, K. Arcand
Scale: Image is about 4.8 arcmin (1.4 light-years) across
Category: Neutron Stars & X-ray Binaries
Coordinates (J2000): RA 08h 35m 20.60s | -45° 10' 35.00"
Constellation: Vela
Observation Date(s): 8 pointings between June and September 2010
Observation Time: 89 hours (3 days 17 hours)
Obs. IDs: 10135-10139, 12073-12075
Instrument: ACIS
Color Code: X-ray: purple (Chandra), light blue (IXPE); Optical: yellow (Hubble)
Distance Estimate: About 1,000 light-years



Fast Facts for Tycho's Supernova Remnant:

Credit: X-ray: NASA/CXC/SAO; Optical: DSS; Image Processing: NASA/CXC/SAO/N. Wolk
Scale: Image is about 12 arcmin (45 light-years) across
Category: Supernovas & Supernova Remnants
Coordinates (J2000): RA 00h 25m 17s | Dec 64° 08' 37"
Constellation: Cassiopeia
Observation Date(s): 14 pointings between Oct 1, 2001 and April 22, 2016
Observation Time: 336 hours (14 days 0 hours 2 min)
Obs. IDs: 115, 3837, 7539, 8551, 10093-10097, 10902-10904, 10906, 15998
Instrument: ACIS
Color Code: X-ray Broadband: red: 0.3-1.2 keV, yellow: 1.2-1.6 keV, cyan: 1.6-2.26 keV, navy: 2.2-4.1 keV, purple: 4.4-6.1 keV; X-ray Motion Shift: orange: 1.7666-1.7812 keV, blue: 1.9564-1.971 keV; Optical: red and blue
Distance Estimate: About 13,000 light-years



Facts for Helix Nebula:

Credit: X-ray: NASA/CXC/SAO; UV: NASA/JPL-Caltech/SSC; Optical: NASA/ STScI/M. Meixner, ESA/NRAO/T.A. Rector; Infrared:NASA/JPL-Caltech/K. Su; Image Processing: NASA/CXC/SAO/N. Wolk and K. Arcand
Scale: Image is about 30 arcmin (5.6 light-years) across
Category: White Dwarfs & Planetary Nebulas
Coordinates (J2000): RA 22h 29m 38.55s | Dec -20° 50' 13.6"
Constellation: Aquarius
Observation Date(s): 2 pointings Nov 17 & 18, 1999
Observation Time: 13 hours and 26 minutes
Obs. IDs: 631, 1480
Instrument: ACIS
Color Code: X-ray: purple; UV: light blue; Optical: red, green, and blue; IR: aqua and red
Distance Estimate: About 650 light-years



Facts for Cat's Eye Nebula:

Credit: X-ray: NASA/CXC/SAO; Optical: NASA/ESA/STScI; Image Processing: NASA/CXC/SAO/J. Major, L. Frattare, K. Arcand
Scale: Image is about 1.7 arcmin (1.5 light-years) across
Category: White Dwarfs & Planetary Nebulas
Coordinates (J2000): RA 17h 58m 33.5s | Dec +66° 37' 59.5"
Constellation: Draco
Observation Date(s): May 10, 2000
Observation Time: 12 hours 48 minutes
Obs. IDs: 630
Instrument: ACIS
Color Code: X-ray: magenta; Optical: red, green, and blue;
Distance Estimate: About 3,000 light-years


Wednesday, April 24, 2024

Hubble Celebrates 34th Anniversary with a Look at the Little Dumbbell Nebula

Little Dumbbell Nebula (WFC3 Image)
Credits: Image: NASA, ESA, STScI




In celebration of the 34th anniversary of the launch of NASA's legendary Hubble Space Telescope on April 24, astronomers took a snapshot of the Little Dumbbell Nebula (also known as Messier 76, M76, or NGC 650/651) located 3,400 light-years away in the northern circumpolar constellation Perseus. The photogenic nebula is a favorite target of amateur astronomers.

M76 is classified as a planetary nebula, an expanding shell of glowing gases that were ejected from a dying red giant star. The star eventually collapses to an ultra-dense and hot white dwarf. A planetary nebula is unrelated to planets, but have that name because astronomers in the 1700s using low-power telescopes thought this type of object resembled a planet.

M76 is composed of a ring, seen edge-on as the central bar structure, and two lobes on either opening of the ring. Before the star burned out, it ejected the ring of gas and dust. The ring was probably sculpted by the effects of the star that once had a binary companion star. This sloughed off material created a thick disk of dust and gas along the plane of the companion's orbit. The hypothetical companion star isn't seen in the Hubble image, and so it could have been later swallowed by the central star. The disk would be forensic evidence for that stellar cannibalism.

The primary star is collapsing to form a white dwarf. It is one of the hottest stellar remnants known at a scorching 250,000 degrees Fahrenheit, 24 times our Sun's surface temperature. The sizzling white dwarf can be seen as a pinpoint in the center of the nebula. A star visible in projection beneath it is not part of the nebula.

Pinched off by the disk, two lobes of hot gas are escaping from the top and bottom of the "belt," along the star's rotation axis that is perpendicular to the disk. They are being propelled by the hurricane-like outflow of material from the dying star, tearing across space at two million miles per hour. That's fast enough to travel from Earth to the Moon in a little over seven minutes! This torrential "stellar wind" is plowing into cooler, slower-moving gas that was ejected at an earlier stage in the star's life, when it was a red giant. Ferocious ultraviolet radiation from the super-hot star is causing the gases to glow. The red color is from nitrogen, and blue is from oxygen.

Given our solar system is 4.6 billion years old, the entire nebula is a flash in the pan by cosmological timekeeping. It will vanish in about 15,000 years.

HUBBLE'S STAR TREKKING

Since its launch in 1990 Hubble has made 1.6 million observations of over 53,000 astronomical objects. To date, the Mikulski Archive for Space Telescopes at the Space Telescope Science Institute in Baltimore, Maryland holds 184 terabytes of processed data that is science-ready for astronomers around the world to use for research and analysis. Since 1990, 44,000 science papers have been published from Hubble observations. The space telescope is the most scientifically productive space astrophysics mission in NASA history. The demand for using Hubble is so high it is currently oversubscribed by a factor of six-to-one.

Most of Hubble's discoveries were not anticipated before launch, such as supermassive black holes, the atmospheres of exoplanets, gravitational lensing by dark matter, the presence of dark energy, and the abundance of planet formation among stars.

Hubble will continue research in those domains and capitalize on its unique ultraviolet-light capability on such topics as solar system phenomena, supernovae outbursts, composition of exoplanet atmospheres, and dynamic emission from galaxies. And Hubble investigations continue to benefit from its long baseline of observations of solar system objects, stellar variable phenomena and other exotic astrophysics of the cosmos.

NASA's James Webb Space Telescope was designed to be meant to be complementary to Hubble, and not a substitute. Future Hubble research also will take advantage of the opportunity for synergies with Webb, which observes the universe in infrared light. The combined wavelength coverage of the two space telescopes expands on groundbreaking research in such areas as protostellar disks, exoplanet composition, unusual supernovae, cores of galaxies and chemistry of the distant universe.

The Hubble Space Telescope has been operating for over three decades and continues to make ground-breaking discoveries that shape our fundamental understanding of the universe. Hubble is a project of international cooperation between NASA and ESA (European Space Agency). NASA's Goddard Space Flight Center in Greenbelt, Maryland, manages the telescope and mission operations. Lockheed Martin Space, based in Denver, Colorado, also supports mission operations at Goddard. The Space Telescope Science Institute in Baltimore, Maryland, which is operated by the Association of Universities for Research in Astronomy, conducts Hubble science operations for NASA.




About This Release

Credits:

Release: NASA, ESA, STScI

Media Contact:

Ray Villard
Space Telescope Science Institute, Baltimore, Maryland

Permissions: Content Use Policy

Contact Us: Direct inquiries to the News Team.

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Tuesday, April 23, 2024

Hubble Goes Hunting for Small Main Belt Asteroids

Wayward Asteroid Photobombs Hubble Snapshot of Galaxy UGC 12158
Credits: Image: NASA, ESA, Pablo García Martín (UAM)
Image Processing: Joseph DePasquale (STScI)
Acknowledgment: Alex Filippenko (UC Berkeley)

Size Distribution for Unknown Asteroids in Hubble Asteroid Hunter Survey
Credits: Illustration: Pablo García Martín (UAM), Elizabeth Wheatley (STScI)




Like boulders, rocks, and pebbles scattered across a landscape, asteroids come in a wide range of sizes. Cataloging asteroids in space is tricky because they are faint and they don't stop to be photographed as they zip along their orbits around the Sun.

Astronomers recently used a trove of archived images taken by NASA's Hubble Space Telescope to visually snag a largely unseen population of smaller asteroids in their tracks. The treasure hunt required perusing 37,000 Hubble images spanning 19 years. The payoff was finding 1,701 asteroid trails, with 1,031 of the asteroids previously uncatalogued. About 400 of these uncatalogued asteroids are below 1 kilometer in size.

Volunteers from around the world known as "citizen scientists" contributed to the identification of this asteroid bounty. Professional scientists combined the volunteers' efforts with machine learning algorithm to identify the asteroids. It represents a new approach to finding asteroids in astronomical archives spanning decades, which may be effectively applied to other datasets, say the researchers.

"We are getting deeper into seeing the smaller population of main belt asteroids. We were surprised with seeing such a large number of candidate objects," said lead author Pablo García Martín of the Autonomous University of Madrid, Spain. "There was some hint of this population existing, but now we are confirming it with a random asteroid population sample obtained using the whole Hubble archive. This is important for providing insights into the evolutionary models of our solar system."

The large, random sample offers new insights into the formation and evolution of the asteroid belt. Finding a lot of small asteroids favors the idea that they are fragments of larger asteroids that have collided and broken apart, like smashed pottery. This is a grinding-down process spanning billions of years.

An alternative theory for the existence of smaller fragments is that they formed that way billions of years ago. But there is no conceivable mechanism that would keep them from snowballing up to larger sizes as they agglomerated dust from the planet-forming circumstellar disk around our Sun. "Collisions would have a certain signature that we can use to test the current main belt population," said co-author Bruno Merín of the European Space Astronomy Centre, in Madrid, Spain.

Amateur Astronomers Teach AI to Find Asteroids

Because of Hubble's fast orbit around the Earth, it can capture wandering asteroids through their telltale trails in the Hubble exposures. As viewed from an Earth-based telescope, an asteroid leaves a streak across the picture. Asteroids "photobomb" Hubble exposures by appearing as unmistakable, curved trails in Hubble photographs.

As Hubble moves around the Earth, it changes its point of view while observing an asteroid, which also moves along its own orbit. By knowing the position of Hubble during the observation and measuring the curvature of the streaks, scientists can determine the distances to the asteroids and estimate the shapes of their orbits.

The asteroids snagged mostly dwell in the main belt, which lies between the orbits of Mars and Jupiter. Their brightness is measured by Hubble's sensitive cameras. And comparing their brightness to their distance allows for a size estimate. The faintest asteroids in the survey are roughly one forty-millionth the brightness of the faintest star that can be seen by the human eye.

"Asteroid positions change with time, and therefore you cannot find them just by entering coordinates, because at different times, they might not be there," said Merín. "As astronomers we don't have time to go looking through all the asteroid images. So we got the idea to collaborate with over 10,000 citizen-science volunteers to peruse the huge Hubble archives."

In 2019 an international group of astronomers launched the Hubble Asteroid Hunter, a citizen-science project to identify asteroids in archival Hubble data. The initiative was developed by researchers and engineers at the European Science and Technology Centre (ESTEC) and the European Space Astronomy Centre's science data center (ESDC), in collaboration with the Zooniverse platform, the world's largest and most popular citizen-science platform, and Google.

A total of 11,482 citizen-science volunteers, who provided nearly 2 million identifications, were then given a training set for an automated algorithm to identify asteroids based on artificial intelligence. This pioneering approach may be effectively applied to other datasets.

The project will next explore the streaks of previously unknown asteroids to characterize their orbits and study their properties, such as rotation periods. Because most of these asteroid streaks were captured by Hubble many years ago, it is not possible to follow them up now to determine their orbits.

The findings are are published in the journal Astronomy and Astrophysics.

To learn how you can participate in citizen science projects related to NASA, visit https://science.nasa.gov/citizen-science/. Participation is open to everyone around the world, not limited to U.S. citizens or residents.

The Hubble Space Telescope has been operating for over three decades and continues to make ground-breaking discoveries that shape our fundamental understanding of the universe. Hubble is a project of international cooperation between NASA and ESA (European Space Agency). NASA's Goddard Space Flight Center in Greenbelt, Maryland, manages the telescope and mission operations. Lockheed Martin Space, based in Denver, Colorado, also supports mission operations at Goddard. The Space Telescope Science Institute (STScI) in Baltimore, Maryland, which is operated by the Association of Universities for Research in Astronomy, conducts Hubble science operations for NASA.




About This Release:

Credits:

Media Contact:

Ray Villard
Space Telescope Science Institute, Baltimore, Maryland

Science Contact

Pablo García Martín
Autonomous University of Madrid, Madrid, Spain

Permissions: Content Use Policy

Contact Us: Direct inquiries to the team.

Related Links and Documents


Monday, April 22, 2024

Twinkle Twinkle Baby Star, ‘Sneezes’ Tell us How You Are

Artist’s conception of a ‘sneeze’ of magnetic field lines, dust, and gas ejected from a baby star.
Credit: ALMA (ESO/NAOJ/NRAO)).
Download image (1.6MB)



Astronomers have discovered the remnants of powerful ‘sneezes’ expelling gas, dust, and electromagnetic energy around stars in the process of forming. The team believes these sneezes help the baby star expel excess magnetic flux, and as such may play a vital role in enabling the star to form.

A star forms from a cloud of gas and dust. Interstellar magnetic field lines pass through these clouds. As the cloud contracts to form the star, the magnetic field lines get pulled along. But observations of young stars show that most of this magnetic energy is lost during the formation process. The question is, where does it go?

Looking for the answer to this question, a team led by Kazuki Tokuda, an astronomer affiliated with NAOJ and Kyushu University, used ALMA (Atacama Large Millimeter/submillimeter Array) to study one of the clouds with a baby star, known as Taurus Dense Core MC 27. This stellar nursery is located approximately 450 light-years from Earth in the direction of the constellation Taurus.

One of the leading theories was that the magnetic field gradually weakened over time as the baby star grew. But as Tokuda explains, “As we analyzed our data, we found something quite unexpected. There were these ‘spike-like’ structures extending a few astronomical units from the protostellar disk. As we dug in deeper, we found that these were spikes of expelled magnetic flux, dust, and gas.”

Tokuda continues, “This is a phenomenon called ‘interchange instability’ where instabilities in the magnetic field react with the different densities of the gases in the protostellar disk, resulting in an outward expelling of magnetic flux. We dubbed this a baby star’s ‘sneeze’ as it reminded us of when we expel dust and air at high speeds.”

Additionally, other spikes were observed several thousands of astronomical units away from the protostellar disk. The team hypothesizes that these were indications of past ‘sneezes.’ And similar spike-like structures have been observed in other young stars, indicating that they may be ubiquitous. These sneezes could help explain how baby stars shed excess magnetic energy and might be a vital part of the star formation process.




Detailed Article(s)


Kyushu University



Release Information

Researcher(s) Involved in this Release

Kazuki Tokuda (Department of Earth and Planetary Science, Faculty of Science, Kyushu University / National Astronomical Observatory of Japan)


Coordinated Release Organization(s)

Kyushu University
National Astronomical Observatory of Japan


Paper(s)

Kazuki Tokuda et al. “Discovery of Asymmetric Spike-like Structures of the 10 au Disk around the Very Low-luminosity Protostar Embedded in the Taurus Dense Core MC 27/L1521F with ALMA”, in The Astrophysical Journal, DOI: 10.3847/1538-4357/ad2f9a



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Sunday, April 21, 2024

Unusually Lightweight Black Hole Candidate Spotted by LIGO

The image shows the coalescence and merger of a lower mass-gap black hole (dark gray surface) with a neutron star (greatly tidally deformed by the black hole's gravity). This still image from a simulation of the merger highlights just the neutron star's lower density components, ranging from 60 grams per cubic centimeter (dark blue) to 600 kilograms per cubic centimeter (white). Its shape highlights the strong deformations of the low-density material of the neutron star Credit: Ivan Markin, Tim Dietrich (University of Potsdam), Harald Paul Pfeiffer, Alessandra Buonanno (Max Planck Institute for Gravitational Physics)

In May 2023, shortly after LIGO (Laser Interferometer Gravitational-wave Observatory) turned back on for its fourth run of observations, it detected a gravitational-wave signal from the collision of an object, most likely a neutron star, with a suspected black hole possessing a mass that is 2.5 to 4.5 times more than that of our Sun. This signal, called GW230529, is intriguing to researchers because the candidate black hole's mass falls within a so-called mass gap between the heaviest known neutron stars, which are slightly more than two solar masses, and the lightest known black holes, which are about five solar masses. While the gravitational-wave signal alone cannot reveal the true nature of this object, future detections of similar events, especially those accompanied by bursts of light, could hold the key to answering the question of how lightweight black holes can be.

"The latest finding demonstrates the impressive science capability of the gravitational-wave detector network, which is significantly more sensitive than it was in the third observing run," says Jenne Driggers (PhD '15), detection lead scientist at LIGO Hanford in Washington, one of two facilities, along with LIGO Livingston in Louisiana, that make up the LIGO Observatory.

LIGO made history in 2015 after carrying out the first direct detection of gravitational waves in space. Since then, LIGO and its partner detector in Europe, Virgo, have detected nearly 100 mergers between black holes, a handful between neutron stars, as well as mergers between neutron stars and black holes. The Japanese detector KAGRA joined the gravitational-wave network in 2019, and the team of scientists who collectively analyze data from all three detectors is known as the LIGO–Virgo–KAGRA (LVK) collaboration. The LIGO observatories are funded by the National Science Foundation (NSF), and were conceived, built, and are operated by Caltech and MIT.<

The latest finding also indicates that collisions involving lightweight black holes may be more common than previously believed.

"This detection, the first of our exciting results from the fourth LIGO–Virgo–KAGRA observing run, reveals that there may be a higher rate of similar collisions between neutron stars and low mass black holes than we previously thought," says Jess McIver, an assistant professor at the University of British Columbia, deputy spokesperson of the LIGO Scientific Collaboration, and a former postdoctoral fellow at Caltech.

Prior to the GW230529 event, one other intriguing mass-gap candidate object had been identified. In that event, which took place in August 2019 and is known as GW190814, a compact object of 2.6 solar masses was found as part of a cosmic collision, but scientists are not sure if it was a neutron star or black hole.

After a break for maintenance and upgrades, the detectors' fourth observing run will resume on April 10, 2024, and will continue until February 2025.

The preprint GW230529 study titled, "Observation of Gravitational Waves from the Coalescence of a 2.5-4.5 M_\odot Compact Object and a Neutron Star," has been posted online.

Read the full story from the LVK collaboration.

Source: Caltech/News



Contact:

>Whitney Clavin
(626) 395‑1944

wclavin@caltech.edu


Saturday, April 20, 2024

‘Swallowed’, torn up or live on: How Earth will fare when the Sun dies

Clumps of debris from a disrupted planetesimal are irregularly spaced on a long and eccentric orbit around the white dwarf. Individual clouds of rubble intermittently pass in front of the white dwarf, blocking some of its light. Because of the various sizes of the fragments in these clumps, the brightness of the white dwarf flickers in a chaotic way.Credit:Dr Mark Garlick/The University of Warwick

Licence type: Attribution (CC BY 4.0)

Our solar system and everything within it - including the Earth - will look very different when the Sun dies.

But whether the planet we call home is “swallowed” up by our dying star or manages to escape its clutches, only time will tell.

The inner planets Mercury and Venus will almost certainly be crushed and engulfed by the Sun, according to a new paper published today in the Monthly Notices of the Royal Astronomical Society (MNRAS).

But even if Earth does outlive its star, unfortunately it still wouldn’t be habitable. On the plus side, it would at least fare better than some of Jupiter’s moons, which an international team of astrophysicists say could be dislodged and shredded as the Sun runs out of energy.

They came up with the terrifying prophecy of what our solar system may look like five billion years from now after studying what happens to planetary systems like our own when their host stars become white dwarfs.

“Whether or not the Earth can just move out fast enough before the Sun can catch up and burn it is not clear, but [if it does] the Earth would [still] lose its atmosphere and ocean and not be a very nice place to live,” explained Professor Boris Gaensicke, of the University of Warwick.

If our planet was engulfed by the Sun, along with Venus and Mercury, this would leave Mars and the four gas giants - Jupiter, Saturn, Uranus and Neptune - orbiting what would ultimately be a white dwarf.

Surviving asteroids and smaller moons would then likely be ripped apart and ground to dust before falling into the dead star, the team of researchers said. Currently the Sun is burning hydrogen at its core, but once this is used up it will expand and become a red giant, before ending up as a white dwarf – the end state of stars when they have burned all their fuel.

Studying white dwarfs is useful because it offers an insight into different aspects of star formation and evolution.

SUMMARY: 'Long-term variability in debris transiting white dwarfs'

Researchers in this study wanted to know what happens to asteroids, moons and planets that pass close to white dwarfs.

What they found is that the fate of these bodies is likely to be extremely violent and catastrophic. They came to this conclusion after analysing the bodies’ transits – dips in the brightness of stars caused by objects passing in front of them.

Unlike the predictable transits caused by orbiting planets around stars, transits caused by debris are oddly shaped, chaotic and disorderly

Lead researcher Dr Amornrat Aungwerojwit, of Naresuan University in Thailand, said: “Previous research had shown that when asteroids, moons and planets get close to white dwarfs, the huge gravity of these stars rips these small planetary bodies into smaller and smaller pieces.”

Collisions between these pieces eventually grind them to dust, which then falls into the white dwarf, enabling researchers to determine what type of material the original planetary bodies were made from.

In this new research, scientists analysed changes in the brightness of stars for 17 years, shedding insight into how these bodies are disrupted. They focused on three different white dwarfs which all behaved very differently.

Professor Gaensicke said: “The simple fact that we can detect the debris of asteroids, maybe moons or even planets whizzing around a white dwarf every couple of hours is quite mind-blowing, but our study shows that the behaviour of these systems can evolve rapidly, in a matter of a few years.

“While we think we are on the right path in our studies, the fate of these systems is far more complex than we could have ever imagined.”

The first white dwarf (ZTF J0328−1219) studied appeared steady and “well behaved” over the last few years, but the authors found evidence for a major catastrophic event around 2010. Another star (ZTF J0923+4236) was shown to dim irregularly every couple of months, and shows chaotic variability on time scales of minutes during these fainter states, before brightening again.

The third white dwarf analysed (WD 1145+017), had been shown by Massachusetts Institute of Technology (MIT) in 2015 to behave close to theoretical predictions, with vast variations in numbers, shapes and depths of transits.

Surprisingly, the transits studied in this research are now gone.

“The system is, overall, very gently getting brighter, as the dust produced by catastrophic collisions around 2015 disperses”, said Professor Gaensicke.

“The unpredictable nature of these transits can drive astronomers crazy – one minute they are there, the next they are gone. And this points to the chaotic environment they are in.”

When asked about the fate of our own solar system, Professor Gaensicke, said: “The sad news is that the Earth will probably just be swallowed up by an expanding Sun, before it becomes a white dwarf.

“For the rest of the solar system, some of the asteroids located between Mars and Jupiter, and maybe some of the moons of Jupiter may get dislodged and travel close enough to the eventual white dwarf to undergo the shredding process we have investigated.”

The paper 'Long-term variability in debris transiting white dwarfs' has been published today in MNRAS.




Media contacts

Sam Tonkin
Royal Astronomical Society
Mob: +44 (0)7802 877700

press@ras.ac.uk

Robert Massey
Royal Astronomical Society
Mob: +44 (0)7802 877699

press@ras.ac.uk

Annie Slinn
University of Warwick
Mob: +44 (0)7392 125 605

annie.slinn@warwick.ac.uk



Science contacts

Professor Boris Gaensicke
University of Warwick
Tel: +60 18 204 3100

boris.gaensicke@warwick.ac.uk

Dr Sukuny Ross
Naresuan University

sukunyaj@nu.ac.th



Further information

The new study 'Long-term variability in debris transiting white dwarfs', Amornrat Aungwerojwit et al., has been published in Monthly Notices of the Royal Astronomical Society.




Notes for editors

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