About the Object
Name: | NGC 6440 | |
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Distance: |
28000 light years | |
Constellation: | Sagittarius | |
Category: | Stars |
Coordinates
Position (RA): | 17 48 52.83 |
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Position (Dec): | -20° 21' 38.76" |
Field of view: | 0.96 x 0.90 arcminutes |
Orientation: | North is 92.5° right of vertical |
Colours & filters
Band | Wavelength | Telescope |
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Infrared | 1.15 μm | James Webb Space Telescope NIRCam |
Infrared | 2.0 μm | James Webb Space Telescope NIRCam |
Infrared | 2.77 μm | James Webb Space Telescope NIRCam |
Infrared | 4.44 μm | James Webb Space Telescope NIRCam |
Webb’s view of NGC 6440 (cropped)
Featured in this new image from the NASA/ESA/CSA James Webb Space Telescope is NGC 6440, a globular cluster that resides roughly 28 000 light-years from Earth in the constellation Sagittarius. The object was first discovered by William Herschel in May of 1786.
Globular clusters like NGC 6440 are roughly spherical, tightly packed, collections of old stars bound together by gravity. They can be found throughout galaxies, but often live on the outskirts. They hold hundreds of thousands to millions of stars that are on average about one light-year apart, but they can be as close together as the size of our Solar System. NGC 6440 is known to be a high-mass and metal-rich cluster that formed and is orbiting within the Galactic bulge, which is a dense, near-spherical region of old stars in the inner part of the Milky Way.
This image was obtained with 2023 data from Webb’s Near-InfraRed Camera (NIRCam) as part of an observation programme to explore the stars in the cluster and to investigate details of the cluster’s pulsars. A pulsar is a highly magnetised, rotating neutron star that emits a beam of electromagnetic radiation from their magnetic poles. To us, that beam appears as a short burst or pulse as the star rotates. Pulsars spin extremely fast. Astronomers have clocked the fastest pulsars at more than 716 rotations per second, but a pulsar could theoretically rotate as fast as 1500 rotations per second before slowly losing energy or breaking apart.
The new data obtained by the science team indicate the first evidence from Webb observations of abundance variations of helium and oxygen in stars in a globular cluster. These results open the window for future, in-depth investigations of other clusters in the Galactic bulge, which were previously infeasible with other telescope facilities given the significant crowding of stars in the cluster and the strong reddening caused by interstellar dust between the cluster and Earth.
You can learn more about this image here.
Credit:ESA/Webb, NASA & CSA, P. Freire
Acknowledgement: M. Cadelano and C. Pallanca
About the Image
Id: | potm2404d | |
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Type: | Observation | |
Release date: | 1 May 2024, 10:00 | |
Size: | 1881 x 1752 px |