James Webb Space Telescope detects new carbon compound in space for the first time
Carbon compounds form the foundations of life
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Scientists have used the James Webb Space Telescope to detect a new carbon compound in space for the first time.
The carbon compound is known as methyl cation, or CH3+.
It is important because it aids the formation of more complex carbon-based molecules.
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Carbon compounds form the foundations of all known life.
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The findings were published in the journal Nature.
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Methyl cation was detected in a young star system known as d203-506, which is located about 1,350 light-years away in the Orion Nebula.
The telescope's detection of key emission lines from the carbon compound determined the discovery.
"This detection not only validates the incredible sensitivity of Webb but also confirms the postulated central importance of CH3+ in interstellar chemistry," Marie-Aline Martin-Drumel of the University of Paris-Saclay in France, a member of the science team, said in a statement.
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NASA says that while the star in d203-506 is a small red dwarf, the system is impacted by strong ultraviolet light from nearby stars.
While UV radiation is typically expected to destroy complex organic molecules, the team predicted that radiation from ultraviolet light may provide the necessary source of energy for the carbon compound to form.
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Once formed, it promotes additional chemical reactions to build more complex carbon molecules.
Scientists believe that most planet-forming disks go through a period of intense UV radiation, because stars tend to form in groups that often include UV-producing stars.
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Molecules seen in the star system are different from typical protoplanetary disks – including no signs of water.
"This clearly shows that ultraviolet radiation can completely change the chemistry of a protoplanetary disk. It might actually play a critical role in the early chemical stages of the origins of life," Olivier Berné of the French National Centre for Scientific Research in Toulouse, lead author of the study, said.