Planck relation


The Planck relation is a fundamental equation in quantum mechanics which states that the photon energy is proportional to the photon frequency :
The constant of proportionality,, is known as the Planck constant. Several equivalent forms of the relation exist, including in terms of angular frequency :
where the reduced Planck constant is.
The relation accounts for the quantized nature of light and plays a key role in understanding phenomena such as the photoelectric effect and black-body radiation.

Spectral forms

Light can be characterized using several spectral quantities, such as frequency, wavelength, wavenumber, and their angular equivalents. These quantities are related through
so the Planck relation can take the following "standard" forms:
as well as the following "angular" forms:
The standard forms make use of the Planck constant. The angular forms make use of the reduced Planck constant. Here is the speed of light.

de Broglie relation

The de Broglie relation, also known as de Broglie's momentum–wavelength relation, generalizes the Planck relation to matter waves. Louis de Broglie argued that if particles had a wave nature, the relation would also apply to them, and postulated that particles would have a wavelength equal to. Combining de Broglie's postulate with the Planck–Einstein relation leads to
or
The de Broglie relation is also often encountered in vector form
where is the momentum vector, and is the angular wave vector.

Bohr's frequency condition

Bohr's frequency condition states that the frequency of a photon absorbed or emitted during an electronic transition is related to the energy difference between the two energy levels involved in the transition:
This is a direct consequence of the Planck–Einstein relation.

Cited bibliography