The Impact‐Parameter Dependence of Electron Stopping in Proton Collisions with Gas and Solid Atoms

Kabachnik, N. M.; Кондратьев, В. Н.; Chumanova, O.V.

doi:10.1002/pssb.2221450107

Cited by 75 publications

(18 citation statements)

References 27 publications

(19 reference statements)

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“…This is due to constraint that the gas target should be dilute enough to suppress multiple scattering and to keep an ultrahigh vacuum ͑UHV͒. For small-angle forward scattering ͑scattering angle: a few mrad͒, however, Auth and Winter 21 observed beautiful line shapes involving elastic and inelastic components using medium energy proton beams and had good agreement between their observation and the first-order perturbation 22 in the mean energy loss and straggling. In order to view the line shapes for a large-angle scattering, it is essential to prepare characteristic surfaces such as adatoms or substrate structures.…”

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confidence: 65%

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Asymmetric line shapes for medium energy H and He ions undergoing a large-angle collision

et al. 2008

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confidence: 65%

“…Based on first-order perturbation theory, Kabachnik et al 22 calculated impact-parameter ͑b͒ dependent electronic energy loss Q͑b͒ assuming a straight ion trajectory. Using the much more reliable coupled-channel method, 18,27 we solve the following timedependent Schrödinger equation for one active electron:…”

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confidence: 99%

Asymmetric line shapes for medium energy H and He ions undergoing a large-angle collision

et al. 2008

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“…The interaction between the incident particle and the core electrons is given by a Coulomb potential screened by the valence electron gas. More details of this calculation are given in [28].…”

Section: Local Stopping Power For Fast Channeled Protonsmentioning

confidence: 99%

Monte Carlo Simulation Analysis of Proton‐Energy Spectra for Axial Channeling in Silicon in the Intermediate Energy Region

Lenkeit

Trikalinos

Balashova

et al. 1990

Physica Status Solidi (b)

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A detailed theoretical analysis of experimental energy spectra of axial-channeled protons transmitted through thin silicon targets is performed by Monte Carlo calculations. Energy spectra are calculated for (1 lo), (1 1 l), and (1 12) channels in the energy region from 50 to 300 keV. The Monte Carlo program is based on the continuum string model. The energy loss on valence electrons is calculated on the basis of a modified Lindhard model for channeling energy loss and the stopping number is taken from the local density approximation of the Lindhard-Winther formalism. The anisotropic distribution of the valence electron density in a semiconductor is taken into account. Stopping due to core electrons is considered by a semiclassical approximation. Multiple scattering and energy straggling are included in the simulation program. The calculated energy spectra and channeling stopping powers are in good agreement with experimental ones. Mit

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“…In fact, the reduction of the stopping power for channeled ions is due to a significant suppression of collisions with small impact parameters. Full calculations of the impact-parameter-dependent energy loss using first-order perturbation theory have been performed only recently, 22 followed later by the first coupled-channel calculations. 23,24 These calculations are time consuming and results are available only for a few selected collision systems.…”

Section: B Impact-parameter-dependent Energy Loss Q"b…mentioning

confidence: 99%

Random and channeling stopping powers of He and Li ions in Si

et al. 2002

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In this work we have measured the electronic stopping powers of 4 He and 7 Li ions for channeling and random directions in Si as a function of the incident ion energy. The channeling (͗100͘ for Li, ͗110͘ and ͗111͘for Li and He͒ and the random ͑Li only͒ measurements cover a wide energy range between 200 keV and 9 MeV. The Rutherford backscattering technique together with different multilayer targets has been employed in the present experiments. The results are compared to calculations carried out in the framework of the unitary convolution approximation, which takes into account the impact-parameter-dependent energy loss for each projectile charge state, with further refinements including screening effects in close collisions between the electrons of the target and the screened projectile.

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The Impact‐Parameter Dependence of Electron Stopping in Proton Collisions with Gas and Solid Atoms

Cited by 75 publications

References 27 publications

Asymmetric line shapes for medium energy H and He ions undergoing a large-angle collision

Asymmetric line shapes for medium energy H and He ions undergoing a large-angle collision

Monte Carlo Simulation Analysis of Proton‐Energy Spectra for Axial Channeling in Silicon in the Intermediate Energy Region

Random and channeling stopping powers of He and Li ions in Si

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