Given that distance scales in Physics range from 10^{− 35} m (the Planck length) to 10²⁶ m (the observable Universe), it is interesting to reflect on why the nanoscale (10^{− 9} m) is so important in materials. There are two main reasons. One is that for pieces of matter smaller than ~ 100 nm their fundamental properties are different to those of the bulk material. The other is that those fundamental properties become dependent on the size of the piece. This is quite alien to our macroscopic view of the world in which we take it for granted that when we cut a piece of material in half its fundamental properties remain unchanged. At the nanometer scale, a number of factors come into play to modify this behaviour. The proportion of atoms that are on the surface atomic layer, whose electronic states are modified relative to interior layers, becomes significant. For example in a 10-nm particle, 10% of the atoms are on the surface layer and this proportion increases to 50% in a 2-nm particle. Also in a metallic particle, the energy separation of conduction electron quantum states becomes significant relative to other energy parameters such as thermal and Zeeman energies. These and other effects mean that as the size of a piece of matter is reduced to ~ 100 nm and below, its electronic, magnetic, optical and chemical properties all start to evolve with size. This evolution is smooth near the upper boundary of the nanoscale region but at small sizes significant changes in behaviour can occur with the removal or addition of a single atom.