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Bumpy Dust Makes Molecular Hydrogen.
The most common element in the universe is hydrogen, and much of that is molecular hydrogen, where two atoms are bonded together. scientists have long puzzled over the question of why all this molecular Hydrogen is out there in space. Researchers from Ohio State University might have found the answer. They've developed a simulation that shows how molecular Hydrogen is more likely to form on interstellar grains of dust which are bumpy, and not smooth.
science fiction writer Harlan Ellison once said that the most common elements in the universe are Hydrogen and stupidity.
While the verdict is still out on the volume of stupidity, scientists have long known that Hydrogen is indeed by far the most abundant element in the universe. When they peer through their telescopes, they see Hydrogen in the vast clouds of dust and gas between stars –- especially in the denser regions that are collapsing to form new stars and planets.
But one mystery has remained: why is much of that Hydrogen in molecular form –- with two Hydrogen atoms bonded together –- rather than its single atomic form? Where did all that molecular Hydrogen come from? Ohio State University researchers recently decided to try to figure it out.
They discovered that one seemingly tiny detail - whether the surfaces of interstellar dust grains are smooth or bumpy - could explain why there is so much molecular Hydrogen in the universe. They reported their results at the 60th International Symposium on Molecular Spectroscopy, held at Ohio State University.
Hydrogen is the simplest atomic element known; it consists of just one Proton and one electron. scientists have always taken for granted the existence of molecular Hydrogen when forming theories about where all the larger and more elaborate molecules in the universe came from. But nobody could explain how so many Hydrogen atoms were able to form molecules - until now.
When it comes to making molecular hydrogen, the ideal microscopic host surface is "less like the flatness of Ohio and more like a Manhattan skyline."
For two Hydrogen atoms to have enough energy to bond in the cold reaches of space, they first have to meet on a surface, explained Eric Herbst, Distinguished University Professor of physics at Ohio State.
Though scientists suspected that space dust provided the necessary surface for such chemical reactions, laboratory simulations of the process never worked. At least, they didn't work well enough to explain the full abundance of molecular Hydrogen that scientists see in space.
Herbst, professor of physics, chemistry, and astronomy, joined with Herma Cuppen, a postdoctoral researcher, and Qiang Chang, a doctoral student, both in physics, to simulate different dust surfaces on a computer. They then modeled the motion of two Hydrogen atoms tumbling along the different surfaces until they found one another to form a molecule.
Given the amount of dust that scientists think is floating in space, the Ohio State researchers were able to simulate the creation of the right amount of hydrogen, but only on bumpy surfaces.
When it comes to making molecular hydrogen, the ideal microscopic host surface is "less like the flatness of Ohio and more like a Manhattan skyline," Herbst said.
The problem with past simulations, it seems, is that they always assumed a flat surface.
Cuppen understands why. "When you want to test something, starting with a flat surface is just faster and easier," she said
She should know. She's an expert in surface science, yet it still took her months to assemble the bumpy dust model, and she's still working to refine it. Eventually, other scientists will be able to use the model to simulate other chemical reactions in space.
In the meantime, the Ohio State scientists are collaborating with colleagues at other institutions who are producing and using actual bumpy surfaces that mimic the texture of space dust. Though real space dust particles are as small as grains of sand, these larger, dime-sized surfaces will enable scientists to test whether different textures help molecular Hydrogen to form in the lab.
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