{"id":779733,"date":"2024-03-28T01:29:54","date_gmt":"2024-03-28T06:29:54","guid":{"rendered":"https:\/\/spaceweekly.com\/?p=779733"},"modified":"2024-03-28T01:29:54","modified_gmt":"2024-03-28T06:29:54","slug":"the-mystery-of-fullerenes-in-space-explained","status":"publish","type":"post","link":"https:\/\/spaceweekly.com\/?p=779733","title":{"rendered":"The mystery of fullerenes in space explained"},"content":{"rendered":"
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\n\n \n Center of the planetary nebula M57, taken by the astrophotographer Dr. Robert Gendler, and John Bozeman. Credit: NASA\/ESA \n <\/figcaption><\/figure>\n<\/p><\/div>\n<\/div>\n
A study from the Instituto de Astrof\u00edsica de Canarias (IAC) which combines laboratory chemistry with astrophysics, has shown for the first time that grains of dust formed by carbon and hydrogen in a highly disordered state, known as HAC, can take part in the formation of fullerenes, carbon molecules which are of key importance for the development of life in the universe, and with potential applications in nanotechnology. The results are published in the journal Astronomy & Astrophysics<\/i>.<\/p>\n\n <\/p>\n<\/section>\n
Fullerenes are carbon molecules that are very big, complex, and highly resistant; their atoms are organized in three-dimensional spherical structures, with a pattern of alternating hexagons and pentagons, shaped like a football (C60<\/sub> fullerenes) or a rugby ball (C70<\/sub> fullerenes).<\/p>\n
These molecules were discovered in the laboratory in 1985, which procured the Nobel Prize for Chemistry for their three discoverers 11 years later. Since then, there have been many instances of observational proof of their existence in space, especially within the gas clouds around old, dying stars the size of the sun, called planetary nebulae, which have been expelled from the outer layers of the stars towards the end of their lives.<\/p>\n
As these molecules are highly stable and difficult to destroy, it is thought that the fullerenes can act as cages for other molecules and atoms so that they could have brought complex molecules to Earth, which gave an impulse to start life. So, their study is important for the understanding of the basic physical processes that take part in the organization of organic material in the universe.<\/p>\n
An unknown chemical footprint<\/h2>\n
Spectroscopy is essential for the search and identification of fullerenes in space. Spectroscopy allows us to study the material composing the universe by analyzing the chemical footprints made by atoms and molecules on the light that reaches us from them.<\/p>\n
A recent study, led entirely by the IAC, has analyzed infrared spectroscopic data obtained previously from telescopes in space, from the planetary nebula Tc1. These spectra show spectral lines indicating the presence of fullerenes but also show broader infrared bands (UIR for their initials in English), which are detected widely in the universe, from the small bodies in the solar system to distant galaxies.<\/p>\n
“The identification of the chemical species which causes this infrared emission, widely present in the universe, was an astrochemical mystery, although it was always thought probable that it is rich in carbon, one of the basic elements of life,” explains Marco A. G\u00f3mez Mu\u00f1oz, an IAC researcher, who led this study.<\/p>\n
A new origin for the fullerenes<\/h2>\n
In order to identify these mysterious bands, the research team reproduced the infrared emission of the planetary nebula Tc 1. Analysis of the emission bands showed the presence of grains of amorphous hydrogenated carbon (HAC). These compounds of carbon and hydrogen in a highly disordered state, very abundant in the envelopes of dying stars, can account for the infrared emission of this nebula.<\/p>\n
“We have combined, for the first time, the optical constants of HAC, obtained from laboratory experiments, with models of photoionization, and by doing this, we have reproduced the infrared emission of the planetary nebula Tc 1, which is very rich in fullerenes,” explains Domingo Anibal Garc\u00eda Hern\u00e1ndez, an IAC researcher who is a co-author of the paper.<\/p>\n
For the research team, the presence of the same object of HAC and fullerenes supports the theory that the fullerenes could have formed during the process of destruction of the dust grains, for example, by interaction with ultraviolet radiation, which is much more energetic than visible light.<\/p>\n
With this result, the scientists have opened the way for future research based on collaboration between laboratory chemistry and astrophysics. “Our work shows clearly the great potential of interdisciplinary science and technology to make basic advances in astrophysics and astrochemistry,” concludes G\u00f3mez Mu\u00f1oz.<\/p>\n
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More information:<\/strong> \n\t\t\t\t\t\t\t\t\t\t\t\tM. A. G\u00f3mez-Mu\u00f1oz et al, Hydrogenated amorphous carbon grains as an alternative carrier of the 9\u201313 \u03bcm plateau feature in the fullerene planetary nebula Tc 1, Astronomy & Astrophysics<\/i> (2024). DOI: 10.1051\/0004-6361\/202349087<\/p>\n<\/p><\/div>\n
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\n\t\t\t\t\t\t\t\t\t\t\t\t\tProvided by \n\t\t\t\t\t\t\t\t\t\t\t\t\t\t\t\t\t\t\t\t\t\t\t\t\t\t\tInstituto de Astrof\u00edsica de Canarias<\/p>\n