soccerballs

In 1985, fullerenes were synthesized for the first time, spherical molecules that can have multiple functions in fields such as nanotechnology or superconductivity. Later, in 2010, was discovered that one type of fullerenes, buckyballs, form naturally in space. Now, a team of Canadian scientists has gone much further, deciphering many of the secrets of these curious structures, thanks to the great help of the James Webb Space Telescope. Small balls that make up a huge ball. Buckyballs are spherical structures, made of 60 carbons, with a conformation of hexagons and pentagons similar to that of a soccer ball. In 2010 they were discovered around a nebula called Tc1. Now, that same nebula has been the goal of James Webb, capable of going much further than they were then. To begin with, delicate rays, ethereal filaments and bright layers of gas along the edge have been detected in the nebula. On the other hand, in the heart of the nebula, a curious structure shaped like an inverted question mark has been detected, whose function is a mystery. But if all that were not enough, it has been seen that those buckyballs that were discovered in 2010 are perfectly organized, forming another hollow sphere, much larger. Chronicle of a death foretold. The stars remain lit thanks to nuclear fusion processes that take place on its surface. This is a very long process, but not eternal. There comes a time when they run out of the elements they use as fuel. When that happens, its outermost layers can break off in the form of gas and dust, giving rise to a nebula, like Tc1. The center, however, becomes a white dwarfa type of cold and dense star. The buckyballs are also possibly remnants of material ejected during the star’s last death throes. James Webb sees what others can’t. James Webb has taken the most precise photo ever taken around Tc1. But, also, thanks to his spectroscopic skillshas studied the composition of all that material ejected by the dying star, including buckyballs. The result, as explained in a statement the authors of the study themselves, is an open window to stellar evolution. Many half-baked studies. There are currently several studies underway aimed at explaining all the new findings around the Tc1 nebula. For now, this discovery has led to tracing the chemistry of carbon, explaining mysterious signals and understanding how organic materials change in extreme environments. In addition, it is a discovery that has challenged traditional views on space chemistry and offered clues about how life may have begun. Turning to the amateur eye. Something curious about the photo that has just been published is that it has not been processed by the scientists who took the images. The lead author of the research, Jan Cami, contacted Katelyn Beecroft, a high school teacher who frequently took her students on field trips to the observatory at the University of Western Ontario. I knew that the teacher is a great fan of astronomy and astrophotography and that she was really good at processing raw images taken by telescopes and enhancing even the most subtle structures that appear in them. He was certainly not wrong to ask for help, as Beercroft’s work has been commendable. Now we just have to understand the reasons for all these new findings. We already have the question, literally. We are missing the answers. Image | Katelyn Beecroft/NASA / ESA / CSA / Western University, J. Cami In Xataka | We have been studying the planets of TRAPPIST-1 for years with great hope. James Webb just knocked it down