Harvard and MIT Scientists Warn That James Webb Data May Not Be What It Seems

Image by NASA/Futurism

What if we told you that the James Webb Space Telescope may be lying to us? 


It's not quite the stuff of meme fodder, but as a new study out of Harvard and MIT warns, there may be a glaring error in the models currently used by astronomers that could leave much of the scope's exoplanet data open to serious misinterpretation. 

In the new study published in the journal Nature Astronomy, astronomers at the storied Cambridge, Massachusetts institutions claim that the way scientists currently interpret the JWST's firehose of data may not be up to snuff — and it may even undermine their ability to tell whether a planet is habitable. 

The researchers determined in their study that researchers' current best opacity model, which they use to suss out how photons pass through a given material, "is not up to par with the precision and quality of data we have from the James Webb telescope," MIT planetary science graduate student Prajwal Niraula said in a university press release. 


MIT assistant professor and study co-leader Julien de Wit explained the telescope's discrepancies by noting that "there is a scientifically significant difference between a compound like water being present at 5 percent versus 25 percent, which current models cannot differentiate." 

"Now that we’re going to the next level with Webb’s precision," the assistant professor noted, "our translation process will prevent us from catching important subtleties, such as those making the difference between a planet being habitable or not." 

To get to that bold warning, the researchers fed eight mocked-up collections of planetary data built to mimic the precision of Webb's information into the same "Rosetta Stone" to see how accurate its translation was. They found that the model "produced wide-ranging predictions for the properties of a planet’s atmosphere," per the MIT announcement, and upon hitting an "accuracy wall" would be unable to differentiate between a planet whose atmospheric temperature is 300 Kelvin and one that burns double that heat at 600. 


"There is so much that could be done if we knew perfectly how light and matter interact," Niraula, the graduate student who worked on the study, said. "We know that well enough around the Earth’s conditions, but as soon as we move to different types of atmospheres, things change, and that’s a lot of data, with increasing quality, that we risk misinterpreting." 

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