Fullerite

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Image:Kohlenstoffnanoroehre Animation.gif Fullerites are the solid-state manifestation of fullerenes and related compounds and materials.

1 Types of fullerite
- 1.1 Ultrahard fullerite
2 See also
3 References
4 External links

[edit] Types of fullerite

Polymerized single walled nanotubes (P-SWNT) are a class of fullerites and are comparable to diamond in terms of hardness. However, due to the way that nanotubes intertwine, P-SWNTs don't have the corresponding crystal lattice that makes it possible to cut diamonds neatly. This same structure results in a less brittle material, as any impact that the structure sustains is spread out throughout the material. Because nanotubes are still very expensive to produce in useful quantities, uses for a material lighter and stronger than steel will have to wait until nanotube production becomes more economically viable.

[edit] Ultrahard fullerite

Scratch caused by ultrahard fullerite on diamond

Ultrahard fullerite (C₆₀) is a form of carbon which has been found to be harder than diamond, and which can be used to create even harder materials, such as aggregated diamond nanorods.

Specifically, it is a unique version of fullerene (which is a class of spherical, ellipsoidal, or tubular carbon molecules) with three-dimensional polymer bonds. This should not be confused with P-SWNT fullerite, which is also a polymerized version of fullerene. It has been shown<ref>http://nanoscan.info/files/article_02.pdf</ref><ref>http://nanoscan.info/files/article_03.pdf 2</ref> that when testing diamond hardness with a scanning force microscope of specific construction<ref>http://nanoscan.info/general.html</ref>, ultrahard fullerite can scratch diamond. In turn, using more accurate measurements, these values are now known for the hardness of diamond. A Type IIa diamond (111) has a hardness value of 167±6 gigapascals (GPa) when scratched with an ultrahard fullerite tip (the hardness of a substance can only be tested properly with a harder substance). A Type IIa diamond (111) has a hardness value of 231±5 GPa when scratched with a diamond tip; this leads to hypothetically inflated values.

Ultrahard fullerite has a hardness value of 310 GPa, though the actual value may range ±40 GPa, since testing done using an ultrahard fullerite tip on ultrahard fullerite will lead to, like diamond on diamond, distorted values. It is thought that beta carbon nitride will have a hardness value, if harder than diamond, less than that of ultrahard fullerite.

C₆₀ has also been used to create an even harder material: aggregated diamond nanorods <ref>http://www.theregister.com/2005/08/30/diamonds_hard_material</ref>