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==Localization and clustering: from bonding to bonds== The metallic bonding in complex compounds does not necessarily involve all constituent elements equally. It is quite possible to have one or more elements that do not partake at all. One could picture the conduction electrons flowing around them like a river around an island or a big rock. It is possible to observe which elements do partake: e.g., by looking at the core levels in an [[X-ray photoelectron spectroscopy]] (XPS) spectrum. If an element partakes, its peaks tend to be skewed. Some intermetallic materials, e.g., do exhibit [[metal cluster]]s reminiscent of molecules; and these compounds are more a topic of chemistry than of metallurgy. The formation of the clusters could be seen as a way to 'condense out' (localize) the electron-deficient bonding into bonds of a more localized nature. [[Hydrogen]] is an extreme example of this form of condensation. At high pressures [[Metallic hydrogen|it is a metal]]. The core of the planet [[Jupiter]] could be said to be held together by a combination of metallic bonding and high pressure induced by gravity. At lower pressures, however, the bonding becomes entirely localized into a regular covalent bond. The localization is so complete that the (more familiar) H<sub>2</sub> gas results. A similar argument holds for an element such as boron. Though it is electron-deficient compared to carbon, it does not form a metal. Instead it has a number of complex structures in which [[icosahedron|icosahedral]] B<sub>12</sub> clusters dominate. [[Charge density wave]]s are a related phenomenon. As these phenomena involve the movement of the atoms toward or away from each other, they can be interpreted as the coupling between the electronic and the vibrational states (i.e. the phonons) of the material. A different such electron-phonon interaction is thought to lead to a very different result at low temperatures, that of [[superconductivity]]. Rather than blocking the mobility of the charge carriers by forming [[electron pair]]s in localized bonds, [[Cooper pairs]] are formed that no longer experience any resistance to their mobility.
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