Event type | Supernova |
---|---|
Date |
c. 9.34 billion years ago (discovered 11 November 2014 by the Hubble Space Telescope) |
Constellation | Leo |
Right ascension | 11h 49m 35.45s [1] |
Declination | 22° 23′ 44.84″ [1] |
Epoch | J2000 |
Distance | c. 14.4 billion ly |
Redshift | z=1.49 [1] |
Host | SP 1149 |
Notable features | First multiply-lensed supernova |
Related media on Commons | |
SN Refsdal is the first detected multiply-lensed supernova, visible within the field of the galaxy cluster MACS J1149+2223. It was named after Norwegian astrophysicist Sjur Refsdal, who, in 1964, first proposed using time-delayed images from a lensed supernova to study the expansion of the universe. [1] [2] [3] The observations were made using the Hubble Space Telescope. [4]
The host galaxy of SN Refsdal is at a redshift of 1.49, corresponding to a comoving distance of 14.4 billion light-years and a lookback time of 9.34 billion years. [5] The multiple images are arranged around the elliptical galaxy at z = 0.54 in a cross-shaped pattern, also known as an " Einstein cross". [1]
After the discovery of the supernova, astronomers predicted that they would be able to see it again in about one year, after the four images had faded away. This is because the initially observed four-image pattern was only one component of the lensing display. The supernova may also have appeared as a single image some 40–50 years ago elsewhere in the cluster field. [1]
The supernova reappeared at the predicted position between 14 November and 11 December 2015 [6] (with the exact date being uncertain by approximately one month which is the interval between two consecutive Hubble observations), [7] in excellent agreement with the blind model predictions made before the reappearance was observed. [8] [9] [10] The time delay between the original quadruplet observed in 2014 and the latest appearance of the supernova in 2015 was used to infer the value of the Hubble constant. This is the first time this technique, originally suggested by Refsdal, has been applied to supernovae. [11]
Using measurements from SN Refsdal and galaxy cluster lens models, astronomers found that the Hubble constant has value H0 = 66.6+4.1
−3.3 km s−1 Mpc−1.
[12]
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cite journal}}
: CS1 maint: numeric names: authors list (
link)
Event type | Supernova |
---|---|
Date |
c. 9.34 billion years ago (discovered 11 November 2014 by the Hubble Space Telescope) |
Constellation | Leo |
Right ascension | 11h 49m 35.45s [1] |
Declination | 22° 23′ 44.84″ [1] |
Epoch | J2000 |
Distance | c. 14.4 billion ly |
Redshift | z=1.49 [1] |
Host | SP 1149 |
Notable features | First multiply-lensed supernova |
Related media on Commons | |
SN Refsdal is the first detected multiply-lensed supernova, visible within the field of the galaxy cluster MACS J1149+2223. It was named after Norwegian astrophysicist Sjur Refsdal, who, in 1964, first proposed using time-delayed images from a lensed supernova to study the expansion of the universe. [1] [2] [3] The observations were made using the Hubble Space Telescope. [4]
The host galaxy of SN Refsdal is at a redshift of 1.49, corresponding to a comoving distance of 14.4 billion light-years and a lookback time of 9.34 billion years. [5] The multiple images are arranged around the elliptical galaxy at z = 0.54 in a cross-shaped pattern, also known as an " Einstein cross". [1]
After the discovery of the supernova, astronomers predicted that they would be able to see it again in about one year, after the four images had faded away. This is because the initially observed four-image pattern was only one component of the lensing display. The supernova may also have appeared as a single image some 40–50 years ago elsewhere in the cluster field. [1]
The supernova reappeared at the predicted position between 14 November and 11 December 2015 [6] (with the exact date being uncertain by approximately one month which is the interval between two consecutive Hubble observations), [7] in excellent agreement with the blind model predictions made before the reappearance was observed. [8] [9] [10] The time delay between the original quadruplet observed in 2014 and the latest appearance of the supernova in 2015 was used to infer the value of the Hubble constant. This is the first time this technique, originally suggested by Refsdal, has been applied to supernovae. [11]
Using measurements from SN Refsdal and galaxy cluster lens models, astronomers found that the Hubble constant has value H0 = 66.6+4.1
−3.3 km s−1 Mpc−1.
[12]
{{
cite journal}}
: CS1 maint: numeric names: authors list (
link)