Etna produces catalyst: direct synthesis of carbon nanotubes with volcanic rock Since their discovery in the early 1990s, carbon nanotubes and carbon nanofibres—tiny structures made of pure carbon—have been used in a wide variety of applications. They have become indispensable in the nanosciences and nanotechnology. However, because their production on an industrial scale remains expensive, their commercial use in such areas as catalysis has remained unthinkable. This could now be changing, thanks to researchers from the Fritz Haber Institute in Berlin: Dang Sheng Su and his co-workers have used igneous rock from Mount Etna to produce carbon nanotubes and fibres directly by deposition from the gas phase. As they explain in the journal Angewandte Chemie, the naturally occurring iron oxide particles in lava make it an effective natural catalyst, possibly smoothing the way to a more efficient production method. Etna is the most active European volcano. During its particularly violent eruptions in 2002 and 2003, several million cubic meters of lava were ejected. The fertility of mineral-rich volcanic soils has long been known; Su and his colleagues wanted to elicit another, completely new sort of “fertility” for science. It could be amazingly helpful in the synthesis of carbon nanotubes and fibres. Lava rock is extremely porous and contains large quantities of finely divided iron oxides. This is just what is needed for the synthesis of these tiny carbon structures. The researchers pulverize the rocks and heat them to 700 °C under a hydrogen atmosphere. This reduces the iron oxide particles to elemental iron. When a mixture of the gases hydrogen and ethylene is directed over the powder, the iron particles catalyse the decomposition of ethylene to elemental carbon. This is deposited on the lava rock in the form of tiny tubes and fibres. The advantages of this new method? The catalyst is produced naturally in large quantities and is thus affordable; the catalytic iron does not need to be deposited on any kind of substrate, as the lava is both catalyst and substrate in one; and this process works without any “wet” chemical steps. The geological aspect of this reaction is also quite interesting: if a carbon source is present, carbon nanotubes and fibres can be formed on minerals at relatively moderate temperatures. Volcanoes produce gases such as methane and hydrogen. Could these forms of carbon already have been generated on Earth millions of years ago? Hydrogen, carbon oxides, and metallic iron are also present in interstellar space—could these little tubes and fibres be produced in space?
The curved sabres used by Muslims against Christian knights in the crusades may have been deadly because Muslim blade-makers used a form of nanotechnology, the steel coming from India, say German experts. The Damascus blades wielded by Muslim fighters, renowned for their exceptional strength, sharp cutting edge and beautiful banding pattern, are believed to have been made from small cakes of steel known as wootz produced in ancient India. A sophisticated treatment was then applied to the steel, but the secrets of the technique were lost in the 18th century and European craftsmen were unable to replicate the process. How medieval blacksmiths overcame the inherent brittleness of the material to create such a perfect finished product has remained a mystery to this day. Now scientists are beginning to uncover the secrets of the Damascus sabre, and the results are surprising. An investigation of the microstructure of one 17th century blade revealed evidence of carbon nanotubes - tiny cylinders of carbon with special properties.