Aggregated diamond nanorod: Difference between revisions
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[[Image:Spot25fig2.jpeg|thumb|right|240px|An Aggregated [[diamond]] nanorod is tested for [[strength]].]] |
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'''Aggregated diamond nanorods''', or '''ADNR'''s, are an [[Carbon#Allotropes|allotrope]] of [[carbon]] believed to be the least compressible material known to humankind, as measured by its [[isothermal bulk modulus]]; aggregated diamond nanorods have a modulus of 491 [[gigapascal]]s (GPa), while a conventional [[diamond]] has a modulus of 442 GPa. ADNRs are also 0.3% denser than regular diamond. The ADNR material is also harder than type IIa diamond and [[ultrahard fullerite]]. |
'''Aggregated diamond nanorods''', or '''ADNR'''s, are an [[Carbon#Allotropes|allotrope]] of [[carbon]] believed to be the least compressible material known to humankind, as measured by its [[isothermal bulk modulus]]; aggregated diamond nanorods have a modulus of 491 [[gigapascal]]s (GPa), while a conventional [[diamond]] has a modulus of 442 GPa. ADNRs are also 0.3% denser than regular diamond. The ADNR material is also harder than type IIa diamond and [[ultrahard fullerite]]. |
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Revision as of 19:12, 3 June 2006
Aggregated diamond nanorods, or ADNRs, are an allotrope of carbon believed to be the least compressible material known to humankind, as measured by its isothermal bulk modulus; aggregated diamond nanorods have a modulus of 491 gigapascals (GPa), while a conventional diamond has a modulus of 442 GPa. ADNRs are also 0.3% denser than regular diamond. The ADNR material is also harder than type IIa diamond and ultrahard fullerite.
A process to produce the substance was discovered by physicists in Germany, led by Natalia Dubrovinskaia, at the University of Bayreuth in 2005. ADNRs are made by compressing allotropic Carbon buckyballs molecules (generally 60 Carbon atoms per molecule) to a pressure of 20 GPa, while at the same time heating to 2500 kelvins, using a unique 5000 metric tonne multi anvil press. The resulting substance is a series of interconnected diamond nanorods, with diameters of between 5 and 20 nanometres and lengths of around 1 micrometre each.
A diamond anvil cell, located at the European Synchrotron Radiation Facility at Grenoble, France, was used to measure the compressibility of the material.