Inelastic mean free path

The inelastic mean free path (IMFP) is an index of how far an electron on average travels through a solid before losing energy.

Universal curve for the electron inelastic mean free path in elements based on equation (5) in.^[1]

If a monochromatic primary beam of electrons is incident on a solid surface, the majority of incident electrons lose their energy because they interact strongly with matter, leading to plasmon excitation, electron-hole pair formation, and vibrational excitation.^[2] The intensity of the primary electrons, $I_{0}$ , is damped as a function of the distance, d, into the solid. The intensity decay can be expressed as follows:

I(d)=I_{0}\ e^{-d\ /\lambda (E)}

where $\textstyle I(d)$ is the intensity after the primary electron beam has traveled through the solid. The parameter $\textstyle \lambda (E)$ , termed the inelastic mean free path (IMFP), is defined as the distance an electron beam can travel before its intensity decays to $\textstyle 1/e$ of its initial value. The inelastic mean free path of electrons can roughly be described by a universal curve, which is the same for all materials.^[1]^[3]

Footnotes

1 2 Seah and Dench (1979)
↑ R. F. Egerton (1996) Electron energy-loss spectroscopy in the electron microscope (Second Edition, Plenum Press, NY) ISBN 0-306-45223-5
↑ Review of electron transport in solids

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[Seah-1] 1 2 Seah and Dench (1979)

[2] R. F. Egerton (1996) Electron energy-loss spectroscopy in the electron microscope (Second Edition, Plenum Press, NY) ISBN 0-306-45223-5

[Werner-3] Review of electron transport in solids

Inelastic mean free path

See also

Footnotes