Brown dwarfs straddle the line between stars and planets. They are too big to be considered planets, yet they do not have sufficient material to fuse hydrogen in their cores to fully develop into stars. They are midway in mass between stars, like our Sun, and giant planets, like Jupiter and Saturn. Sometimes described as failed stars, they do not have an internal source of energy, so they are cold, very faint, and keep on cooling over time.
The brown dwarf, named ULAS J222711-004547, caught the researchers’ attention for its extremely red appearance compared to “normal” brown dwarfs. Further observations with the Very Large Telescope (VLT) in Chile and the use of an innovative data analysis technique have shown that the reason for its peculiarity is the presence of a thick layer of clouds in its upper atmosphere.
“These are not the type of clouds that we are used to seeing on Earth,” said Federico Marocco from the University of Hertfordshire in the United Kingdom. “The thick clouds on this particular brown dwarf are mostly made of mineral dust, like enstatite and corundum. Not only have we been able to infer their presence, but we have also been able to estimate the size of the dust grains in the clouds.”
The size of the dust grains influences the color of the sky. A red sky on the brown dwarf suggests an atmosphere loaded with dust and moisture particles. If our morning skies are red, it is because clear skies to the east permit the Sun to light the undersides of moisture-bearing clouds coming in from the west. Conversely, in order to see red clouds in the evening, sunlight must have a clear path from the west in order to illuminate moisture-bearing clouds moving off to the east. However, the recently discovered brown dwarf ULAS J222711-004547 has a very different atmosphere where the sky is always red.
The giant planets of the solar system, like Jupiter and Saturn, show various cloud layers, including ammonia and hydrogen sulphide, as well as water vapor. The atmosphere observed in this particular brown dwarf is hotter — with water vapor, methane, and probably some ammonia — but, unusually, it is dominated by clay-sized mineral particles.
Getting a good understanding of how such an extreme atmosphere works will help astronomers better understand the range of atmospheres that can exist.
“Being one of the reddest brown dwarfs ever observed, ULAS J222711-004547 makes an ideal target for multiple observations to understand how the weather is in such an extreme atmosphere,” said Avril Day-Jones from the University of Hertfordshire’s Center for Astrophysics Research. “By studying the composition and variability in luminosity and colors of objects like this, we can understand how the weather works on brown dwarfs and how it links to other giant planets.”
