Posted on 04/13/2007 1:19:08 PM PDT by Red Badger
The crystal structure of COF-108. Synthesized only from light elements (H,B,C,O) COF-108 is the lowest-density crystal ever produced (0.17 g/cm3).
Chemists at UCLA have designed new organic structures for the storage of voluminous amounts of gases for use in alternative energy technologies.
The research, published in the journal Science, demonstrates how the design principles of reticular chemistry have been used to create three-dimensional covalent organic frameworks, which are entirely constructed from strong covalent bonds and have high thermal stability, high surface areas and extremely low densities.
Reticular chemistry deals with linking molecular building blocks by strong bonds into predetermined structures which can be functionalized and their metrics altered at will. The principles of reticular chemistry and the ability to construct chemical structures from these molecular building blocks has led to the creation of new classes of materials of exceptional variety.
Omar Yaghi (earlier post), UCLA professor of chemistry and biochemistry, led the team which comprises chemists from the Center for Reticular Chemistry at UCLA's California NanoSystems Institute and the departments of chemistry and biochemistry at UCLA.
The covalent organic frameworks, or COFs (pronounced "coffs"), one of these new classes of materials, are the first crystalline porous organic networks. A member of this series, COF-108, has the lowest density reported of any crystalline material, with a surface area of more than 4,500 square meters per gram.
One gram, unraveled, could cover the surface area of approximately 30 tennis courts.
These are the first materials ever made in which the organic building blocks are linked by strong bonds to make covalent organic frameworks. The key is that COFs are composed of light elements, such as boron, carbon and oxygen, which provide thermal stability and great functionality. —Omar Yaghi
In the push to develop methods to control greenhouse gas emissions, some of the biggest challenges have been finding ways to store hydrogen for use as a fuel, to use methane as an alternative fuel, and to capture and store carbon dioxide from power plant smokestacks before it reaches the atmosphere. Yaghi and his colleagues believe COFs are uniquely suited for all these applications because of their functional flexibility and their extremely light weight, high porosity and thermal stability.
The research was funded by BASF, the National Science Foundation and the US Department of Energy.
A year ago, Yaghi and his team achieved hydrogen storage concentrations of up to 7.5 wt% in Metal Organic Framework (MOF) material—exceeding the DOE target of 6.5% by 2010 for application in hydrogen fuel-cell cars. (Earlier post.) BASF has licensed the technology and is moving forward on commercialization of MOFs.
Resources:
“Designed Synthesis of 3D Covalent Organic Frameworks”; Hani M. El-Kaderi, Joseph R. Hunt, José L. Mendoza-Cortés, Adrien P. Côté, Robert E. Taylor, Michael O'Keeffe, Omar M. Yaghi;; Science 13 April 2007: Vol. 316. no. 5822, pp. 268 - 272 DOI: 10.1126/science.1139915
Omar Yaghi research
Coke dealers have been doing this for decades..........
ping!
That's roughly 11 lbs. per cubic foot, about the density of snow.
If it is highly porous, how does it capture and store gases?
yitbos
It captures them by adsorbing them onto its surface; a process where the gas molecules pass close enough to the surface of the filtering medium to get stuck to it. More surface area means more filtering capacity per volume of filtering medium.
If it is highly porous, how does it capture and store gases?
Like a sponge holds water or other liquids. In the “holes”.........
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