Bohr radius

Template:Unit of length In the Bohr model of the structure of an atom, put forward by Niels Bohr in 1913, electrons orbit a central nucleus. The model says that the electrons orbit only at certain distances from the nucleus, depending on their energy. In the simplest atom, hydrogen a single electron orbits the nucleus and its smallest possible orbit, with lowest energy, is called the Bohr radius and is the most likely position of the electron.

According to 2006 CODATA the Bohr radius of hydrogen has a value of 5.2917720859(36)×10⁻¹¹ m (i.e., approximately 53 pm or 0.53 ångströms).^[1][2] This value can be computed in terms of other physical constants:

${\displaystyle a_{0}={\frac {4\pi \epsilon _{0}\hbar ^{2}}{m_{e}e^{2}}}={\frac {\hbar }{m_{e}\,c\,\alpha }}}$

where:

${\displaystyle \epsilon _{0}\ }$ is the permittivity of free space

${\displaystyle \hbar \ }$ is the reduced Planck's constant

${\displaystyle m_{e}\ }$ is the electron rest mass

${\displaystyle e\ }$ is the elementary charge

${\displaystyle c\ }$ is the speed of light in vacuum

${\displaystyle \alpha \ }$ is the fine structure constant

While the Bohr model does not correctly describe an atom, the Bohr radius keeps its physical meaning as a characteristic size of the electron cloud in a full quantum-mechanical description. Thus the Bohr radius is often used as a unit in atomic physics, see atomic units.

Note that the definition of Bohr radius does not include the effect of reduced mass, and so it is not precisely equal to the orbital radius of the electron in a hydrogen atom in the more physical model where reduced mass is included. This is done for convenience: the Bohr radius as defined above appears in equations relating to atoms other than hydrogen, where the reduced mass correction is different. If the definition of Bohr radius included the reduced mass of hydrogen, it would be necessary to include a more complex adjustment in equations relating to other atoms.

The Bohr radius of the electron is one of a trio of related units of length, the other two being the Compton wavelength of the electron ${\displaystyle \lambda _{e}\ }$ and the classical electron radius ${\displaystyle r_{e}\ }$. The Bohr radius is built from the electron mass ${\displaystyle m_{e}}$, Planck's constant ${\displaystyle \hbar \ }$ and the electron charge ${\displaystyle e\ }$. The Compton wavelength is built from ${\displaystyle m_{e}\ }$, ${\displaystyle \hbar \ }$ and the speed of light ${\displaystyle c\ }$. The classical electron radius is built from ${\displaystyle m_{e}\ }$, ${\displaystyle c\ }$ and ${\displaystyle e\ }$. Any one of these three lengths can be written in terms of any other using the fine structure constant ${\displaystyle \alpha \ }$:

${\displaystyle r_{e}={\frac {\alpha \lambda _{e}}{2\pi }}=\alpha ^{2}a_{0}}$

The Bohr radius including the effect of reduced mass can be given by the following equation:

${\displaystyle \ a_{0}^{*}\ ={\frac {\lambda _{p}+\lambda _{e}}{2\pi \alpha }}}$,

where

${\displaystyle \lambda _{p}\ }$ is the Compton wavelength of the proton.

${\displaystyle \lambda _{e}\ }$ is the Compton wavelength of the electron.

${\displaystyle \alpha \ }$ is the fine structure constant.

In the above equation, the effect of the reduced mass is achieved by using the increased Compton wavelength, which is just the Compton wavelengths of the electron and the proton added together.

See also

Bohr model

Notes and references

1. fundamental physical constants, NIST
2. The number in parentheses (36) denotes the uncertainty of the last digits.

External links

• Length Scales in Physics: the Bohr Radius