Perseushopen

Perseushopen
Central regions Perseus galaxy cluster.jpg
De centrala delarna av Perseus-hopen.
Observationsdata
StjärnbildPerseus
Rektascension03t 18m
Deklination+41° 30′ ″
Antal galaxer>1000[1]
Rödförskjutning0,01790[1] km/s
Avstånd240,05 mlijoner[1] l
Hopens diameter863 bågminuter[1] '
Ljusaste medlemmenNGC 1275[2]
Se också: Galaxhop Lista över galaxhopar

Perseushopen, eller Abell 426, är en galaxhop i stjärnbilden Perseus. Galaxhopen innehåller mer än 1000 galaxer och har ett ungefärligt avstånd av 240 miljoner ljusår.[1] Den är en regelbunden galaxhop som har en utsträckning på stjärnhimlen av ungefär fyra grader[2] och är ett av de massivaste astronomiska objekt forskarna känner till.[3][4]

Perseushopen är den ljusstarkaste hopen på himlen vid observation på röntgenbandet. Hopen innehåller radiokällan 3C 84 vilken för tillfället blåser bubblor av relativistisk plasma in mot hopens centrum. Dessa kallas radiobubblor och ses som hål på röntgenbilder av hopen. I hopens centrum finns ett antal ljusa galaxer, som domineras av NGC 1275,[2] där röntgenstrålningen är starkast.

År 2003 registrerade astronomerna den lägsta ton som någonsin frambringats i universum, efter 53 timmars observationer gjorda av Chandra-teleskopet. Det finns ingen möjlighet för ett mänskligt öra att uppfatta tonen, eftersom den ligger 57 oktaver under tangenterna i mitten av ett piano. Perioden för dess sväningar är 9,6 miljoner år.[5] Ljudvågorna genererades uppenbarligen vid den våldsamma aktiviteten då radiobubblor blåstes upp vid den aktiva galaxkärnan i NGC 1275, vilken tros innehålla ett svart hål i sitt centrum.[3]

2014 uppfångade vidare oidentifierade signaler som kunde tyda på att mörk materia upptäckts.[3][4]

Bildgalleri

  • Perseushopen fotograferad av amatörastronom.

    Perseushopen fotograferad av amatörastronom.

  • Perseushopen fotograferad med Chandra-teleskopet.

    Perseushopen fotograferad med Chandra-teleskopet.

  • Fler foton med Chandra-teleskopet, som visar den turbulens som finns i Perseushopen.

    Fler foton med Chandra-teleskopet, som visar den turbulens som finns i Perseushopen.

Referenser

Noter

  1. ^ [a b c d e] ”NASA/IPAC Extragalactic Database” (på engelska). Results for Perseus Cluster. http://ned.ipac.caltech.edu/cgi-bin/nph-objsearch?objname=Perseus+CLUSTER. Läst 2 september 2017. 
  2. ^ [a b c] ”Perseushopen”. Nationalencyklopedin. Bokförlaget Bra böcker AB, Höganäs. http://www.ne.se/uppslagsverk/encyklopedi/l%C3%A5ng/perseushopen. Läst 2 september 2017. 
  3. ^ [a b c] Lars Wærstad (25 juni 2014). ”NASA har oppdaget mystisk signal – Romorganisasjonen aner ikke hva det er” (på norska). side3.no. Arkiverad från originalet den 9 september 2017. https://web.archive.org/web/20170909143225/http://www.side3.no/vitenskap/nasa-har-oppdaget-mystisk-signal/8459320.html. Läst 2 september 2017. 
  4. ^ [a b] Geir Barstein (27 juni 2014). ”Mystisk rontgensignal” (på norska). Dagbladet. Arkiverad från originalet den 9 september 2017. https://web.archive.org/web/20170909143225/http://www.side3.no/vitenskap/nasa-har-oppdaget-mystisk-signal/8459320.html. Läst 2 september 2017. 
  5. ^ Fabian, A. C.; Sanders, J. S.; Allen, S. W.; Crawford, C. S.; Iwasawa, K.; Johnstone, R. M.; Schmidt, R. W.; Taylor, G. B. (2003 tidskrift=Monthly Notices of the Royal Astronomical Society) (på engelska). A Deep Chandra observation of the Perseus cluster: shocks and ripples. "344". sid. L43-L47. http://adsabs.harvard.edu/abs/2003MNRAS.344L..43F. Läst 2 september 2017. 

Media som används på denna webbplats

NASA-PerseusGalaxyCluster-ChandraXRayObservatory-20140624.jpg
A new study of the central region of the Perseus galaxy cluster, shown in this image, using NASA's Chandra X-ray Observatory and 73 other clusters with ESA's XMM-Newton has revealed a mysterious X-ray signal in the data. This signal is represented in the circled data points in the inset, which is a plot of X-ray intensity as a function of X-ray energy. The signal is also seen in over 70 other galaxy clusters using XMM-Newton. This unidentified X-ray emission line - that is, a spike of intensity at a very specific energy, in this case centered on about 3.56 kiloelectron volts (keV) - requires further investigation to confirm both the signal's existence and nature as described in the latest Chandra press release.

One intriguing possible explanation of this X-ray emission line is that it is produced by the decay of sterile neutrinos, a type of particle that has been proposed as a candidate for dark matter. While holding exciting potential, these results must be confirmed with additional data to rule out other explanations and determine whether it is plausible that dark matter has been observed.

There is uncertainty in these results, in part, because the detection of this emission line is pushing the capabilities of both Chandra and XMM-Newton in terms of sensitivity. Also, there may be explanations other than sterile neutrinos if this X-ray emission line is deemed to be real. For example, there are ways that normal matter in the cluster could have produced the line, although the team's analysis suggested that all of these would involve unlikely changes to our understanding of physical conditions in the galaxy cluster or the details of the atomic physics of extremely hot gases.

This image is Chandra's latest view of hot gas in the central region of the Perseus Cluster, where red, green, and blue show low, medium, and high-energy X-rays respectively. It combines data equivalent to more than 17 days worth of observing time taken over a decade with Chandra. The Perseus Cluster is one of the most massive objects in the Universe, and contains thousands of galaxies immersed in an enormous cloud of superheated gas. In Chandra's X-ray image, enormous bright loops, ripples, and jet-like streaks throughout the cluster can be seen. The dark blue filaments in the center are likely due to a galaxy that has been torn apart and is falling into NGC 1275 (a.k.a. Perseus A), the giant galaxy that lies at the center of the cluster.
Perseus Cluster - Abell 426.jpg
Författare/Upphovsman: David Chifiriuc, Licens: CC BY-SA 4.0
Perseus Cluster (Abell 426) - photographed with amateur equipment

Skywatcher 10" Quattro Newtonian, Skywatcher AZ-EQ6 GT mount, Skywatcher f4 aplanatic coma corrector, Skywatcher 9x50 finderscope, Lacerta MGEN-II Superguider

Canon EOS100D camera, 12x10 min exposures, ISO 800, 14x10 min dark frames, processing made with DeepSkyStacker 3.3.4 and Adobe Photoshop CS5

Baiculesti commune, Arges county, Romania

Avg. outside temperature: -5ºC
14-296-GalaxyClusters-PerseusVirgo-ChandraXRay-20141027.jpg
October 27, 2014

RELEASE 14-296 NASA’S Chandra Observatory Identifies Impact of Cosmic Chaos on Star Birth

http://www.nasa.gov/press/2014/october/nasa-s-chandra-observatory-identifies-impact-of-cosmic-chaos-on-star-birth/

IMAGE:
Chandra observations of the Perseus and Virgo galaxy clusters suggest turbulence may be preventing hot gas there from cooling, addressing a long-standing question of galaxy clusters do not form large numbers of stars.

DESCRIPTION:
The same phenomenon that causes a bumpy airplane ride, turbulence, may be the solution to a long-standing mystery about stars’ birth, or the absence of it, according to a new study using data from NASA’s Chandra X-ray Observatory.

Galaxy clusters are the largest objects in the universe, held together by gravity. These behemoths contain hundreds or thousands of individual galaxies that are immersed in gas with temperatures of millions of degrees.

This hot gas, which is the heftiest component of the galaxy clusters aside from unseen dark matter, glows brightly in X-ray light detected by Chandra. Over time, the gas in the centers of these clusters should cool enough that stars form at prodigious rates. However, this is not what astronomers have observed in many galaxy clusters.

“We knew that somehow the gas in clusters is being heated to prevent it cooling and forming stars. The question was exactly how,” said Irina Zhuravleva of Stanford University in Palo Alto, California, who led the study that appears in the latest online issue of the journal Nature. “We think we may have found evidence that the heat is channeled from turbulent motions, which we identify from signatures recorded in X-ray images.”

Prior studies show supermassive black holes, centered in large galaxies in the middle of galaxy clusters, pump vast quantities of energy around them in powerful jets of energetic particles that create cavities in the hot gas. Chandra, and other X-ray telescopes, have detected these giant cavities before.

The latest research by Zhuravleva and her colleagues provides new insight into how energy can be transferred from these cavities to the surrounding gas. The interaction of the cavities with the gas may be generating turbulence, or chaotic motion, which then disperses to keep the gas hot for billions of years.

“Any gas motions from the turbulence will eventually decay, releasing their energy to the gas,” said co-author Eugene Churazov of the Max Planck Institute for Astrophysics in Munich, Germany. “But the gas won’t cool if turbulence is strong enough and generated often enough.”

The evidence for turbulence comes from Chandra data on two enormous galaxy clusters named Perseus and Virgo. By analyzing extended observation data of each cluster, the team was able to measure fluctuations in the density of the gas. This information allowed them to estimate the amount of turbulence in the gas.

“Our work gives us an estimate of how much turbulence is generated in these clusters,” said Alexander Schekochihin of the University of Oxford in the United Kingdom. “From what we’ve determined so far, there’s enough turbulence to balance the cooling of the gas.

These results support the “feedback” model involving supermassive black holes in the centers of galaxy clusters. Gas cools and falls toward the black hole at an accelerating rate, causing the black hole to increase the output of its jets, which produce cavities and drive the turbulence in the gas. This turbulence eventually dissipates and heats the gas.

While a merger between two galaxy clusters may also produce turbulence, the researchers think that outbursts from supermassive black holes are the main source of this cosmic commotion in the dense centers of many clusters.

NASA's Marshall Space Flight Center in Huntsville, Alabama, manages the Chandra program for NASA's Science Mission Directorate in Washington. The Smithsonian Astrophysical Observatory in Cambridge, Massachusetts, controls Chandra's science and flight operations.

An interactive image, podcast, and video about these findings are available at: http://chandra.si.edu

For more Chandra images, multimedia and related materials, visit:

http://www.nasa.gov/chandra
Central regions Perseus galaxy cluster.jpg
An accumulation of 270 hours of Chandra observations of the central regions of the Perseus galaxy cluster reveals evidence of the turmoil that has wracked the cluster for hundreds of millions of years. One of the most massive objects in the universe, the cluster contains thousands of galaxies immersed in a vast cloud of multimillion degree gas with the mass equivalent of trillions of suns.

Enormous bright loops, ripples, and jet-like streaks are apparent in the image. The dark blue filaments in the center are likely due to a galaxy that has been torn apart and is falling into NGC 1275, a.k.a. Perseus A, the giant galaxy that lies at the center of the cluster.

Image is 284 arcsec across. RA 03h 19m 47.60s Dec +41° 30' 37.00" in Perseus. Observation dates: 13 pointings between August 8, 2002 and October 20, 2004. Color code: Energy (Red 0.3-1.2 keV, Green 1.2-2 keV, Blue 2-7 keV). Instrument: ACIS.