Atomic units: Difference between revisions

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The atomic units, abbreviated a.u. is a set of units used in atomic calculations.^[1][2] In the a.u. system any four of the five quantities charge e, mass m_e, action ℏ, length a₀, and energy E_h may be taken as base quantities, and other quantities are derived.^[3] A listing of numerical values in terms of SI units can be found on the NIST website.^[4]

Example units

The expressions for a few example atomic units in terms of formulas in SI units are discussed next.

Mass

The atomic unit of mass is the electron mass, m_e.^[5] However, confusingly, the terminology "atomic unit of mass" often is taken instead to refer to the unified atomic mass unit, the Dalton, symbol u. The Dalton is defined as 1/12 the mass of a free carbon 12 atom,^[6] with a value of 1.660538921(73) × 10^-27 kg.,^[7] or 931.494 061(21) MeV.^[8] A proton has a mass of approximately 1.007 276 466 812 u.^[9] The electron mass is about 5.485 799 0946 × 10^-4 u.^[10]

Length

In SI units the a.u. unit of length, the Bohr radius a₀ or bohr, is:^[11]

${\displaystyle a_{0}=\alpha /4{\rm {\pi }}R_{\infty }=4{\rm {\pi }}\epsilon _{0}\hbar ^{2}/m_{\rm {e}}e^{2}=\mathrm {0.52917721092(17)\ \times \ 10^{-10}\ m} \ ,}$

where R_∞ is the Rydberg constant, e is the elementary charge, ε₀ is the electric constant, ℏ is the reduced Planck's constant h/(2π), m_e is the electron mass, and where the (dimensionless) fine structure constant α is given by (in SI units):

${\displaystyle \alpha ={\frac {e^{2}}{4\pi \varepsilon _{0}\hbar c_{0}}}\ ,}$

and has the value:^[12]

${\displaystyle \alpha =\mathrm {7.2973525698(24)\times 10^{-3}} =\mathrm {1/137.035999074(44)} \ .}$

The Bohr radius was the distance of an electron from the nucleus of a hydrogen atom predicted by the Bohr theory of the atom, which required an integer number of wavelengths around the electron orbit.^[13] In modern quantum mechanics the Bohr radius is the distance of maximum likelihood for finding the electron in the hydrogen atom in its ground state. ^[14]

Energy

The unit of energy, the hartree, is the energy of two a.u. charges separated by one bohr in a medium of permittivity given by 1 a.u. of permittivity, 4πε₀:^[15]

${\displaystyle E_{h}={\frac {1}{4\pi \varepsilon _{0}}}{\frac {e^{2}}{a_{0}}}}$ ${\displaystyle =\mathrm {4.35974434(19)\ \times \ 10^{-18}\ J} \ .}$

Time

Somewhat unusually, time is a derived quantity, ℏ/E_h, with the interpretation as the period of an electron circling in the first Bohr orbit divided by 2π.^[16][17]

${\displaystyle \hbar /E_{h}=\mathrm {2.418884326502(12)} \ \times \ 10^{-17}\ \mathrm {s} }$

Velocity

Using the unit of time, and the expression for the hartree, the a.u. unit of velocity is one bohr per a.u. unit of time:

${\displaystyle v_{B}=a_{0}/(\hbar /E_{h})={\frac {e^{2}}{4\pi \varepsilon _{0}\hbar }}=\alpha c_{0}\ .}$

Here c₀ is the SI units defined speed of light in classical vacuum and α is the fine structure constant. Its value is:^[18]

${\displaystyle a_{0}/(\hbar /E_{h})=\mathrm {2.18769126379(71)} \times 10^{6}\mathrm {m/s} \ .}$

The a.u. unit of velocity changes size with refinement in measurement of the fine structure constant. However, the defined value of c₀ = v_B/α is unaffected by such refinements. See the articles speed of light and metre for more detail about the defined value c₀ = 299 792 458 m/s (exactly).

Tabulation

Evidently in atomic units, if we choose e, ℏ, m_e, and a₀ as the four basic units, then these entities all become 1 in algebraic expressions, and because a₀ = (4πε₀)(ℏ/e)²/m_e, it follows that 4πε₀ = 1 as well, defining the a.u. unit of permittivity. The hartree, E_h = (4πε₀)⁻¹ e²/a₀ also is automatically 1.

Here, c₀ = SI units defined value for the speed of light in classical vacuum, ε₀ is the electric constant, α = fine structure constant and μ_B is the Bohr magneton.^[20]

Notes