- We’d like to study exoplanet atmospheres, but that’s hard because you can’t separate them from the star. Brown dwarfs are a good substitute because they are kind of like really big exoplanets.
- There’s chemistry happening inside the atmosphere of a brown dwarf, and chemicals will get transported up or down from where they are made. The detection of HCN in the brown dwarf spectrum means that some of our models for brown dwarfs are wrong.
You could try reading the linked paper. If I am reading it correctly, basically, we have atmospheric models for brown dwarfs and the presence of C2H2 and compounds cannot be explained by those models. So they think there are more complex atmospheric processes like aurora or lightning behind it.
Yeah I definitely attempted but stellar chemistry isn’t something I’d say I’m comfortable with particularly at the level required to comprehend a paper. That said, the subject is very interesting to me.
Can someone explain why this is significant? Is this a precursor for something such as life?
According to the paper’s abstract,
- We’d like to study exoplanet atmospheres, but that’s hard because you can’t separate them from the star. Brown dwarfs are a good substitute because they are kind of like really big exoplanets.
- There’s chemistry happening inside the atmosphere of a brown dwarf, and chemicals will get transported up or down from where they are made. The detection of HCN in the brown dwarf spectrum means that some of our models for brown dwarfs are wrong.
One neat thing I know about HCN and early chemical evolution is that some DNA bases can be created from HCN polymerisation.
https://pubmed.ncbi.nlm.nih.gov/31491/
Like if you look at adenine, it is 'just' N-C-N-C all the way round.
You could try reading the linked paper. If I am reading it correctly, basically, we have atmospheric models for brown dwarfs and the presence of C2H2 and compounds cannot be explained by those models. So they think there are more complex atmospheric processes like aurora or lightning behind it.
Yeah I definitely attempted but stellar chemistry isn’t something I’d say I’m comfortable with particularly at the level required to comprehend a paper. That said, the subject is very interesting to me.
Arxiv paper https://arxiv.org/abs/2502.13610
About 0.81 Jupiter radii with 50-70 times of mass? That gravity must hurt.