phonon
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- Scholars at Harvard - Phonons and Photons
- International Journal of Scientific & Engineering Research - A Short Review of Phonon Physics
- National Center for Biotechnology Information - Phonon representations
- Royal Society of Chemistry Publishing - Magnon–phonon coupling: from fundamental physics to applications
- University of Cambridge - Department of Applied Mathematics and Theoretical Physics - Phonons
- Key People:
- Bertram N. Brockhouse
- Related Topics:
- quasiparticle
- On the Web:
- International Journal of Scientific & Engineering Research - A Short Review of Phonon Physics (Oct. 15, 2024)
phonon, in condensed-matter physics, a unit of vibrational energy that arises from oscillating atoms within a crystal. Any solid crystal, such as ordinary table salt (sodium chloride), consists of atoms bound into a specific repeating three-dimensional spatial pattern called a lattice. Because the atoms behave as if they are connected by tiny springs, their own thermal energy or outside forces make the lattice vibrate. This generates mechanical waves that carry heat and sound through the material. A packet of these waves can travel throughout the crystal with a definite energy and momentum, so in quantum mechanical terms the waves can be treated as a particle, called a phonon. A phonon is a definite discrete unit or quantum of vibrational mechanical energy, just as a photon is a quantum of electromagnetic or light energy.
Phonons and electrons are the two main types of elementary particles or excitations in solids. Whereas electrons are responsible for the electrical properties of materials, phonons determine such things as the speed of sound within a material and how much heat it takes to change its temperature.
In addition to their importance in the thermal and acoustic properties, phonons are essential in the phenomenon of superconductivity—a process in which certain metals such as lead and aluminum lose all their electrical resistance at temperatures near absolute zero (−273.15 °C; −459.67 °F). Ordinarily, electrons collide with impurities as they move through a metal, which results in a frictional loss of energy. In superconducting metals at sufficiently low temperatures, however, electrons—which ordinarily repel each other—slightly attract each other through the intermediate effect of phonons. The result is that the electrons move through the material as a coherent group and no longer lose energy through individual collisions. Once this superconducting state has been achieved, any initial flow of electrical current will persist indefinitely.
In 1986 a new class of materials, called high-temperature superconductors, was discovered; it is not known if the electron-phonon interaction is the basis for the superconducting behaviour of these materials. See also low-temperature phenomena.