The Local Plasma Frequency Approach in Description of the Impact-Parameter Dependence of Energy Loss

Khodyrev, V.A.

doi:10.1238/physica.regular.064a00053

Cited by 4 publications

(3 citation statements)

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“…The representation (14) permits us to present [12] a comprehensive description of energy loss also for the uniform gas of interacting electrons. This is possible if the response of electrons on the projectile field is treated in the linear RPA approach.…”

Section: Discussionmentioning

confidence: 99%

“…In section 2, these features are analysed on the qualitative level. Using the introduced representation of energy loss, the Lindhard-Scharff model [11] for the stopping cross section (the local plasma frequency, LPF, approach) can be generalized [12] to describe E(b) in the linear response approach. The combination of this model with the exact description of energy loss to free electrons results in a general model [13] where both the Barkas and Bloch corrections to E(b) are described in a general scheme.…”

Section: A Khodyrevmentioning

confidence: 99%

“…This estimate, however, loses its validity when the angle of diffraction of the electron wave, diff ≈ 1/vs ad = ω/v 2 , has a larger value. In this case, min ≈ diff and L is given by the expression (12).…”

Section: The Qualitative Analysismentioning

confidence: 99%

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The energy loss in the collision of a moving charged projectile with a free electron is described in a rigorous approach. The collision is treated as stationary scattering of an electron in the projectile Coulomb field. In the laboratory frame, the picture can be represented as a spatial distribution of energy losses to the electron. It has been shown that the local rate of the energy gain can be presented as a product of the induced electron current and the projectile electric field. The analytical results and numerical calculations reveal a principal disagreement with the generally recognized condition for the classical description, η = Z 1 e 2 /hv 1 (Z 1 e and v are, respectively, the charge and velocity of the projectile): for any value of η, the quantum effects appear to be significant in the close vicinity of the projectile trajectory (small impact parameters) restricted by the distance ∼λ =h/mv. Essentially, the problem has been cleared in the qualitative analysis of collisions with electron wavepackets. The main results of the Bloch theory are reproduced in a simpler way. The clearer basis permits us to eliminate the ambiguity in the interpretation of the origin of the Bloch correction, which reflects in fact the evolution of the classical features in the quantum mechanical picture.where ψ is the logarithmic derivative of the -function. The correction is even over the projectile charge, L ≈ −1.202η 2 at small η.

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Section: Discussionmentioning

confidence: 99%

Section: A Khodyrevmentioning

confidence: 99%