The international study – the first of its kind – reveals the extreme atmospheric conditions on the celestial objects, which are swathed in swirling clouds of hot sand amid temperatures of 950C.
Cosmic weather
Using NASA’s powerful James Webb Space Telescope (JWST), researchers set out to capture the weather on a pair of brown dwarfs – cosmic bodies that are bigger than planets but smaller than stars.
These brown dwarfs, named collectively as WISE 1049AB, are the brightest and closest objects of their type to Earth, around six light years away.
Shifting brightness
The team tracked each brown dwarf’s atmosphere by measuring the light waves emitted from their surfaces, which change as more or less cloudy regions revolve in and out of view.
By visualising this data through light curves – a plot of how the brightness of light from each object changes over time – the team was able to build up a detailed 3D picture of how the brown dwarfs’ weather changed over the course of a full rotation or day, between five and seven hours.
The team was also able to plot how the light from each object varied by wavelength, to demonstrate the presence and complex interplay of gases such as water, methane, and carbon monoxide in their atmospheres.
Missing link
The insights may help astronomers develop the understanding of brown dwarfs as a potential missing link between stars and planets – promising new insights into both.
By observing the infrared part of the light spectrum, the JWST is able to observe wavelengths of light that are blocked by our own atmosphere.
This capability opens frontiers in the study of the early universe, star formation, and so-called exoplanets such as brown dwarfs which lie beyond our solar system.
Distant worlds
The latest study builds on previous studies of brown dwarfs, which have mainly been confined to capturing static snapshots of their atmosphere on only one side. This approach is limited, as brown dwarfs are known to rotate relatively quickly and their weather can vary greatly over time, researchers say.
Their findings will pave the way for more detailed studies into brown dwarfs and other distant celestial objects.
The study, published in Monthly Notices of the Royal Astronomical Society, was led by the University of Edinburgh in collaboration with researchers from Trinity College Dublin, the University of Virginia, and other institutes from around the world.