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Asoft gamma repeater (SGR) is anastronomical object which emits large bursts ofgamma-rays andX-rays at irregular intervals. It is conjectured that they are a type ofmagnetar or, alternatively,neutron stars with fossildisks around them.[1]
On March 5, 1979[2] a powerfulgamma-ray burst was noted. As a number of receivers at different locations in theSolar System[3] saw the burst at slightly different times, its direction could be determined, and it was shown to originate from near asupernova remnant in theLarge Magellanic Cloud.[2][3]
Over time it became clear that this was not a normal gamma-ray burst. Thephotons were less energetic in the soft gamma-ray and hard X-ray range, and repeated bursts came from the same region.
AstronomerChryssa Kouveliotou of the Universities Space Research Association (USRA) at NASA's Marshall Space Flight Center decided to test the hypothesis that soft gamma repeaters were magnetars.[2][3] According to the hypothesis, the bursts would cause the object to slow down its rotation. In 1998,[2][3] she made careful comparisons of the periodicity of soft gamma repeaterSGR 1806-20. The period had increased by 0.008 seconds since 1993, and she calculated that this would be explained by a magnetar with amagnetic-field strength of 8×1010teslas (8×1014gauss). This was enough to convince the international astronomical community that soft gamma repeaters are indeed magnetars.
An unusually spectacular soft gamma repeater burst wasSGR 1900+14 observed on August 27, 1998. Despite the large distance to this SGR, estimated at 20,000 light years, the burst had large effects on the Earth's atmosphere. The atoms in theionosphere, which are usually ionized by the Sun's radiation by day and recombine to neutral atoms by night, were ionized at nighttime at levels not much lower than the normal daytime level. The Rossi X-Ray Timing Explorer (RXTE), anX-raysatellite, received its strongest signal from this burst at this time, even though it was directed at a different part of the sky, and should normally have been shielded from the radiation.
Known soft gamma repeaters include:[4]
| Object | Discovery | Notes |
|---|---|---|
| SGR 0525−66 | 1979 | |
| SGR 1806−20 | 1979/1986 | The most powerful soft gamma repeater burst yet recorded was observed coming from this object on December 27, 2004. |
| SGR 1900+14 | 1979/1986 | 20,000 lyr away; powerful, affected theEarth's atmosphere. |
| SGR 1627−41 | 1998 | |
| SGR J1550−5418[5] | 2008 | Rotates once every 2.07 seconds, holds the record for the fastest-spinningmagnetar. |
| SGR 0501+4516[6] | 2008 | 15,000 lyr away; X-ray outburst detected bySwift satellite 22 August 2008. |
| SGR J1745−2900 | 2013 | A soft gamma repeater orbiting theblack hole inSagittarius A*. |
| SGR 1935+2154 | 2014 | 30,000 lyr away; First ever detectedfast radio burst inside the Milky Way, and the first ever to be linked to a known source. |
The numbers give the position in the sky, for example, SGR 0525-66 has aright ascension of 5h25m and adeclination of −66°. The date of discovery sometimes appears in a format such as 1979/1986 to refer to the year the object was discovered, in addition to the year soft gamma repeaters were recognized as a separate class of objects rather than "normal" gamma-ray bursts.
Scientists note 20th anniversary of March 5, 1979 gamma-ray burst event
| Types | |
|---|---|
| Single pulsars |
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| Binary pulsars | |
| Properties | |
| Related | |
| Discovery | |
| Satellite investigation | |
| Other | |
