# Difference between revisions of "Planck constant"

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− | An absolute physical constant, having the dimension of action (energy | + | {{TEX|done}} |

+ | An absolute physical constant, having the dimension of action (energy$\times$time). Planck's constant $h$ is | ||

− | + | \[6.626\,070\,15\times10^{-34}\,\mathrm J\,\mathrm s.\] | |

− | + | It was first introduced by M. Planck (1900) in a paper on the radiation of light, in which he suggested that the energy $E$ of a photon (an electromagnetic wave) is $E=h\nu$, where $\nu$ is the frequency of the wave. Later, when quantum mechanics arose, Planck's constant was used in the definition of major quantum-mechanical quantities (momentum and energy operators, etc.) and appeared in almost all equations of quantum mechanics. | |

− | Planck's constant characterizes in a certain sense the limits of the use of classical mechanics: The laws of quantum mechanics deviate substantially from those of classical mechanics only for physical systems for which the characteristic distances, velocities and masses are such that the corresponding characteristic action is of the same order as | + | Planck's constant characterizes in a certain sense the limits of the use of classical mechanics: The laws of quantum mechanics deviate substantially from those of classical mechanics only for physical systems for which the characteristic distances, velocities and masses are such that the corresponding characteristic action is of the same order as $h$. In a formal mathematical treatment this means that the equations of quantum mechanics go over to the corresponding classical equations as $h\to0$. |

− | The constant | + | The constant $h$ may be replaced by the constant $\hbar=h/(2\pi)$, which is also called Planck's constant. |

## Latest revision as of 16:10, 21 May 2019

An absolute physical constant, having the dimension of action (energy$\times$time). Planck's constant $h$ is

\[6.626\,070\,15\times10^{-34}\,\mathrm J\,\mathrm s.\]

It was first introduced by M. Planck (1900) in a paper on the radiation of light, in which he suggested that the energy $E$ of a photon (an electromagnetic wave) is $E=h\nu$, where $\nu$ is the frequency of the wave. Later, when quantum mechanics arose, Planck's constant was used in the definition of major quantum-mechanical quantities (momentum and energy operators, etc.) and appeared in almost all equations of quantum mechanics.

Planck's constant characterizes in a certain sense the limits of the use of classical mechanics: The laws of quantum mechanics deviate substantially from those of classical mechanics only for physical systems for which the characteristic distances, velocities and masses are such that the corresponding characteristic action is of the same order as $h$. In a formal mathematical treatment this means that the equations of quantum mechanics go over to the corresponding classical equations as $h\to0$.

The constant $h$ may be replaced by the constant $\hbar=h/(2\pi)$, which is also called Planck's constant.

#### Comments

#### References

[a1] | L.I. Schiff, "Quantum mechanics" , McGraw-Hill (1968) |

[a2] | A. Messiah, "Quantum mechanics" , I-II , North-Holland (1961) |

[a3] | Th.T. Taylor, "Mechanics: classical and quantum" , Pergamon (1976) pp. 124ff |

**How to Cite This Entry:**

Planck constant.

*Encyclopedia of Mathematics.*URL: http://www.encyclopediaofmath.org/index.php?title=Planck_constant&oldid=12737