Boomerang-tågen

Boomerang tågen. Foto:NASA/ESA.

Boomerang-tågen (også kaldet Butterfly-tågen[1]) er en protoplanetarisk tåge beliggende ca. 5.000 lysår fra Jorden i stjernebilledet Kentauren. Tågens temperatur er målt til at være 1° K, det koldeste sted som kendes udenfor et laboratorium. Boomerang-tågen dannes af gas, som udstødes fra en stjerne i dens centrum, og gassen breder sig udad med en fart på omkring 164 km/s, mens den hurtigt udvider sig på sin vej ud i rummet. Denne udvidelse er grunden til tågens meget lave temperatur.

Boomerang-tågen fotograferedes i detaljer af Hubble-rumteleskopet i 1998. Det menes, at tågen er en stjerne eller et stjernesystem, som udvikler sig mod den fase, der involverer dannelsen af en planetarisk tåge.

Astronomerne Keith Taylor og Mike Scarrott kaldte den 'Boomerang-tågen', da de første gang observerede den i 1980 med det engelsk-australske teleskop på observatoriet Siding Spring. Da de ikke kunne se de detaljer, som Hubble afslørede senere, så de kun en let asymmetri i tågens flige, hvilket antydede en kurveform af lighed med en boomerang. Hubbles billeder med deres høje opløsning antyder, at 'butterfly-tågen' ville have været et mere beskrivende navn.

Boomerang-tågen er et særligt sted i universet. I 1995 afslørede astronomer ved at benytte det svenske ESO submillimeter teleskop i Chile, at den er det koldeste sted i universet, som hidtil er fundet. Med en temperatur på −272 °C er den kun 1 grad C varmere end det absolutte nulpunkt (den nedre grænse for alle temperaturer). Selv den kosmiske baggrundsstråling, som er en efterglød fra Big Bang, er med sine −270 °C varmere end denne tåge. Tågen er også det eneste objekt, der indtil nu er fundet med lavere temperatur end baggrundsstrålingen.[1]

Noter

  1. ^ a b Stephen Cauchi i The Sydney Morning Herald, 21. februar 2003

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Image of the planet Jupiter and one of its moons
Boomerang nebula.jpg

The Boomerang Nebula is a young planetary nebula and the coldest object found in the Universe so far. The NASA/ESA Hubble Space Telescope image is yet another example of how Hubble's sharp eye reveals surprising details in celestial objects.

This NASA/ESA Hubble Space Telescope image shows a young planetary nebula known (rather curiously) as the Boomerang Nebula. It is in the constellation of Centaurus, 5000 light-years from Earth. Planetary nebulae form around a bright, central star when it expels gas in the last stages of its life.

The Boomerang Nebula is one of the Universe's peculiar places. In 1995, using the 15-metre Swedish ESO Submillimetre Telescope in Chile, astronomers Sahai and Nyman revealed that it is the coldest place in the Universe found so far. With a temperature of -272C, it is only 1 degree warmer than absolute zero (the lowest limit for all temperatures). Even the -270C background glow from the Big Bang is warmer than this nebula. It is the only object found so far that has a temperature lower than the background radiation.

Keith Taylor and Mike Scarrott called it the Boomerang Nebula in 1980 after observing it with a large ground-based telescope in Australia. Unable to see the detail that only Hubble can reveal, the astronomers saw merely a slight asymmetry in the nebula's lobes suggesting a curved shape like a boomerang. The high-resolution Hubble images indicate that 'the Bow tie Nebula' would perhaps have been a better name.

The Hubble telescope took this image in 1998. It shows faint arcs and ghostly filaments embedded within the diffuse gas of the nebula's smooth 'bow tie' lobes. The diffuse bow-tie shape of this nebula makes it quite different from other observed planetary nebulae, which normally have lobes that look more like 'bubbles' blown in the gas. However, the Boomerang Nebula is so young that it may not have had time to develop these structures. Why planetary nebulae have so many different shapes is still a mystery.

The general bow-tie shape of the Boomerang appears to have been created by a very fierce 500 000 kilometre-per-hour wind blowing ultracold gas away from the dying central star. The star has been losing as much as one-thousandth of a solar mass of material per year for 1500 years. This is 10-100 times more than in other similar objects. The rapid expansion of the nebula has enabled it to become the coldest known region in the Universe.

The image was exposed for 1000 seconds through a green-yellow filter. The light in the image comes from starlight from the central star reflected by dust particles.
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