New material could help with carbon storage

Feb 27, 2014 by Tom Simons
Xiao Cheng Zeng (right) and Jun Dai. In the background is a computer simulation of the new material, silicon carbonate, illustrating its three-layer structure. Credit: Craig Chandler, University Communications

New research led by University of Nebraska-Lincoln chemist Xiao Cheng Zeng has led to the discovery of a new material that could have significant implications for a variety of challenges, from carbon dioxide storage to planetary science and solid lubrication.

At first glance, there wouldn't seem to be much of a connection between and quartz. But in scientific terms, they are actually quite close as they are oxides of the first two elements in a chemical group in the periodic table (Group IV)—carbon for dry ice (frozen ) and silicon for quartz.

In 2011, European researchers announced the discovery of a new substance called silicon carbonate when they combined dry ice and silicon dioxide (quartz) under high pressure. They were unable to determine the material's crystal structure, however, and the question caught the attention of Zeng and his colleagues, who took up the challenge and spent almost a year in modeling possible structures on the University of Nebraska's Holland Computing Center supercomputer.

"We did an exhaustive search of possible solid structures for a given ratio of carbon dioxide and silicon dioxide," said Zeng, Ameritas University Professor of chemistry. "We did an extensive structure search of thousands of crystal structures before we identified one highly stable one."

That highly stable form, Zeng said, consists of one silicon atom, two carbon atoms and six oxygen atoms, or SiC2O6.

The result was reported in the Feb. 27 issue of Physical Review Letters X, the highly selective, online-only, fully open-access journal of the American Physical Society. It is the first time UNL research has been published in the three-year-old journal.

"One of the potential applications is carbon dioxide storage," Zeng said. "We predict that under high pressure, about 200,000 atmospheres, carbon dioxide can combine with silicon dioxide to form a new crystal form that is a possible sequestration form.

"This solid is somewhere between dry ice and quartz, and in the past, people didn't imagine that there was something in between. Something in the middle is very hard for chemists to imagine, but we provide a candidate for something in the middle."

Zeng said the predicted crystal may also provide an important clue to the makeup of terrestrial planets and satellites since and carbon dioxide in its gaseous and frozen forms are common components of those bodies. With a layered structure similar to graphite's, the silicon carbonate crystal also has potential as a solid lubricant.

"The structure we saw is a three-layered structure where the middle layer is silicon," he said. "The layers can slip and shear, making it a good solid lubricant."

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Scottingham
5 / 5 (2) Feb 27, 2014
Only 200k atmospheres? Sounds cost effective to me! Not.
Mike_Massen
1 / 5 (1) Feb 27, 2014
Ah ha, you Scottingham, could do with some high end Science in material properties & processes.
For the macro you may be well right but hmmm, for the micro & nano, I really really doubt it.

Superposition & other quantum style processes may well result in an equilibrium which spouts out the material indicated without the gross need to expend the energy on any normal scale to achieve & wait around for it to happen, the nano has interesting properties & such things happen "more often than not", it is a Huge chemical engineering playground worthy of exploration, experience so far suggests that, depending upon design, large energy expenditures are not required as nature provides many (quantum type) diverse 'loopholes' to allow "things to happen" & very nicely too for some, I might add :-)

Cheers