We are on the cover of Surface Science (Farahnaz Maleki made this very nice picture) and check out the tweet of @ElsevierPhysics:
Glass can be formed naturally; for example in volcanoes or when lightning strikes a sandy beach and it has been produced by humans for thousands of years. Glasses can take on many different appearances, colors, and properties. Thus, it may be surprising that our understanding of the exact structure of glass is not complete, even after such a long time. Very often, you will hear glasses described as amorphous. This word is derived from Greek and means without shape. So we have a rough idea that glass is somehow shapeless. In the following we will see, how we can investigate the atomic arrangement in glass using modern techniques.
...continue reading "How we can see the structure of glass"
The presence of nanoparticles in industrial processes dates back well before the advent of nanotechnology  : carbon nanoparticles as rubber additives for tires  or titania nanoparticles for pigmentary applications  represent a paradigm of mass production of nanoscale objects. The success of manufacturing approaches based on the assembling of nanoparticles is largely determined by the established infrastructure and customer base with cost reduction as a general benchmark. Several techniques for the synthesis of metal oxides have been developed: sol-gel processing,  chemical vapor deposition,  hydrolysis process.  Among different processes for the production of nanoparticles, gas-phase routes are very popular both for large scale production and for fundamental studies.  Producing the nanoclusters in the gasphase makes it for instance possible to obtain clean particles without contaminants. With the so called low-energy cluster beam deposition, it is possible to produce gas-phase clusters in vast amounts! For a deposition area of 10×10 cm for a thin film of 30 nm thickness, the deposition time is around 10 minutes.
...continue reading "Large-scale production of gas-phase nanoparticles"