2001
DOI: 10.1002/sia.973
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Electron transport in solids for quantitative surface analysis

Abstract: The influence of electron transport on the signal generation process in electron beam techniques is reviewed. A survey of the fundamental physical quantities for the electron-solid interaction is presented and sources for these quantities in the literature as well as semi-empirical formulae are given. The theoretical approaches used to describe multiple scattering in solids are outlined. These include the partial intensity approach and the continuous slowing down approximation to describe multiple energy losse… Show more

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Cited by 316 publications
(296 citation statements)
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References 168 publications
(269 reference statements)
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“…The transport approximation for elastic scattering and its limits of applicability are appropriately discussed in Ref. [14].…”
Section: Monte Carlomentioning
confidence: 99%
“…The transport approximation for elastic scattering and its limits of applicability are appropriately discussed in Ref. [14].…”
Section: Monte Carlomentioning
confidence: 99%
“…14 Contrary to the continuous energy-loss models (e.g., from stopping power theory) widely used for studying irradiation effects in bulk solids, MC models of materials with restricted dimensions (e.g., CNTs and nanodevices in general) must account for secondary-electron cascade generation through the use of discrete (or single-scattering) energy-loss models. [15][16][17] Such models will also complement current computational studies of high-energy electron-beam (e.g., from a transmission electron microscope, TEM) irradiation effects in CNTs lying on substrates from backscattered electrons. 18,19 Binary collision theory has been widely used in this context due to its computational convenience, despite its wellknown simplistic description of the materials excitation properties.…”
mentioning
confidence: 95%
“…In each inelastic scattering event, a portion of the electron kinetic energy is transferred to a water molecule, ultimately creating a valence excitation in this molecule. A single primary Auger electron can create tens of valence excitations within a few femtoseconds [26][27][28][29][30]. The detected XE photons result from the radiative decay of the core-ionized molecule [ Fig.…”
mentioning
confidence: 99%