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Using Quasars to Map the Magellanic Corona

Illustration showing the Milky Way, the Small Magellanic Cloud, and the Large Magellanic Cloud, with three bright background quasars.

Researchers have used spectroscopic observations of ultraviolet light from quasars to detect and map the Magellanic Corona, a diffuse halo of hot, supercharged gas surrounding the Small and Large Magellanic Clouds. Shown in purple, the corona stretches more than 100,000 light-years from the main mass of stars, gas, and dust that make up the Magellanic Clouds, intermingling with the hotter and more extensive corona that surrounds the Milky Way. 

The Magellanic Clouds, dwarf galaxies roughly 160,000 light-years from Earth, are the largest of the Milky Way’s satellites and are thought to be on their first in-falling passage around the Milky Way. This journey has begun to unravel what were once barred spirals with multiple arms into more irregular-shaped galaxies with long tails of debris. The corona is thought to act as a buffer protecting the dwarf galaxies’ vital star-forming gas from the gravitational pull of the much larger Milky Way.

The detection of the Magellanic Corona was made by analyzing patterns in ultraviolet light from 28 distant background quasars. As the quasar light passes through the corona, certain wavelengths (colors) of ultraviolet light are absorbed. The quasar spectra become imprinted with the distinct signatures of carbon, oxygen, and silicon ions that make up the corona gas. Because each quasar probes a different part of the corona, the research team was also able to show that the amount of gas decreases with distance from the center of the Large Magellanic Cloud.

This study used archival observations of quasars from Hubble’s Cosmic Origins Spectrograph (COS) and the Far Ultraviolet Spectroscopic Explorer (FUSE). Quasars have also been used to probe the Magellanic Stream, outflows from the Milky Way, and the halo surrounding the Andromeda Galaxy.

About the Data

  • Data Description
    Data DescriptionProposal: A description of the observations, their scientific justification, and the links to the data available in the science archive.
    Science Team: The astronomers who planned the observations and analyzed the data. "PI" refers to the Principal Investigator.

    Magellanic Corona mapped using archival HST/COS spectra of 28 background UV-bright quasars, along with archival FUSE spectra of 6 of these quasars. Research was funded through HST Archival Research Program 16363.  

  • Instrument
    InstrumentThe science instrument used to produce the data.
    Hubble Space Telescope: Cosmic Origins Spectrograph; Far Ultraviolet Spectroscopic Explorer
  • Filters
    FiltersThe camera filters that were used in the science observations.
    HST/COS gratings: G130M (0.1150 - 0.1450 microns) and G160M (0.1405 - 0.1775 microns)
  • Object Name
    Object NameA name or catalog number that astronomers use to identify an astronomical object.
    Large and Small Magellanic Clouds
  • Object Description
    Object DescriptionThe type of astronomical object.
    Irregular dwarf galaxies
  • Release Date
    September 28, 2022
  • Science Release
    Hubble Detects Protective Shield Defending a Pair of Dwarf Galaxies
    Read the release
  • Credit
    NASA, ESA, Leah Hustak (STScI)

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Details

Last Updated
Mar 28, 2025
Contact
Media

Claire Andreoli
NASA’s Goddard Space Flight Center
Greenbelt, Maryland
claire.andreoli@nasa.gov

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