Oscillator strength

In spectroscopy, oscillator strength is a dimensionless quantity that expresses the probability of absorption or emission of electromagnetic radiation in transitions between energy levels of an atom or molecule.[1][2][3]

Theory

An atom or a molecule can absorb light and undergo a transition from one quantum state to another.

The oscillator strength f_{12} of a transition from a lower state |1\rangle to an upper state |2\rangle may be defined by


  f_{12} = \frac{2 }{3}\frac{m_e}{\hbar^2}(E_2 - E_1) \sum_{\alpha=x,y,z}
 | \langle 1 m_1 | R_\alpha | 2 m_2 \rangle |^2,

where m_e is the mass of an electron and \hbar is the reduced Planck constant. The quantum states |n\rangle, n= 1,2, are assumed to have several degenerate sub-states, which are labeled by m_n. "Degenerate" means that they all have the same energy E_n. The operator R_x is the sum of the x-coordinates r_{i,x} of all N electrons in the system, etc.:


  R_\alpha = \sum_{i=1}^N r_{i,\alpha}.

The oscillator strength is the same for each sub-state |n m_n\rangle.

Thomas–Reiche–Kuhn sum rule

To make equations of the previous section applicable to the states belonging to the continuum spectrum, they should be rewritten in terms of matrix elements of the momentum \boldsymbol{p}. In absence of magnetic field, the Hamiltonian can be written as H=\frac{1}{2m}\boldsymbol{p}^2+V(\boldsymbol{r}), and calculating a commutator [H,x] in the basis of eigenfunctions of H results in the relation between matrix elements


  x_{nk}=-\frac{i\hbar/m}{E_n-E_k}(p_x)_{nk}.
.

Next, calculating matrix elements of a commutator [p_x,x] in the same basis and eliminating matrix elements of x, we arrive at


  \langle n|[p_x,x]|n\rangle=\frac{2i\hbar}{m}\sum_{k\neq n} \frac{|\langle n|p_x|k\rangle|^2}{E_n-E_k}.

Because [p_x,x]=-i\hbar, the above expression results in a sum rule


  \sum_{k\neq n}f_{nk}=1,\,\,\,\,\,f_{nk}=-\frac{2}{m}\frac{|\langle n|p_x|k\rangle|^2}{E_n-E_k},

where f_{nk} are oscillator strengths for quantum transitions between the states n and k. This is the Thomas-Reiche-Kuhn sum rule, and the term with k=n has been omitted because in confined systems such as atoms or molecules the diagonal matrix element \langle n|p_x|n\rangle=0 due to the time inversion symmetry of the Hamiltonian H. Excluding this term eliminates divergency because of the vanishing denominator.[4]

Sum rule and electron effective mass in crystals

In crystals, energy spectrum of electrons has a band structure E_n(\boldsymbol{p}). Near the minimum of an isotropic energy band, electron energy can be expanded in powers of \boldsymbol{p} as E_n(\boldsymbol{p})=\boldsymbol{p}^2/2m^* where m^* is the electron effective mass. It can be shown[5] that it satisfies the equation


  \frac{2}{m}\sum_{k\neq n}\frac{|\langle n|p_x|k\rangle|^2}{E_k-E_n}+\frac{m}{m^*}=1.

Here the sum runs over all bands with k\neq n. Therefore, the ratio m/m^* of the free electron mass m to its effective mass m^* in a crystal can be considered as the oscillator strength for the transition of an electron from the quantum state at the bottom of the n band into the same state.[6]

See also

References

  1. W. Demtröder (2003). Laser Spectroscopy: Basic Concepts and Instrumentation. Springer. p. 31. ISBN 978-3-540-65225-0. Retrieved 26 July 2013.
  2. James W. Robinson (1996). Atomic Spectroscopy. MARCEL DEKKER Incorporated. pp. 26–. ISBN 978-0-8247-9742-3. Retrieved 26 July 2013.
  3. Hilborn, Robert C. (1982). "Einstein coefficients, cross sections, f values, dipole moments, and all that". American Journal of Physics 50 (11): 982. arXiv:physics/0202029. Bibcode:1982AmJPh..50..982H. doi:10.1119/1.12937. ISSN 0002-9505.
  4. Edward Uhler Condon; G. H. Shortley (1951). The Theory of Atomic Spectra. Cambridge University Press. p. 108. ISBN 978-0-521-09209-8. Retrieved 26 July 2013.
  5. Luttinger, J. M.; Kohn, W. (1955). "Motion of Electrons and Holes in Perturbed Periodic Fields". Physical Review 97 (4): 869. doi:10.1103/PhysRev.97.869.
  6. Sommerfeld, A.; Bethe, H. (1933). "Elektronentheorie der Metalle". Aufbau Der Zusammenhängenden Materie. Berlin: Springer. p. 333. doi:10.1007/978-3-642-91116-3_3. ISBN 978-3-642-89260-8.


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