The Sherman function in highly relativistic elastic electron–atom scattering

Jakubaßa-Amundsen, Doris H.; Barday, R.

doi:10.1088/0954-3899/39/2/025102

Cited by 21 publications

(17 citation statements)

References 41 publications

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“…The phase shift analysis [55,56] remains the same as applied at the lower energies, using equations (27) and (28)for the calculation of f q ( ) and g(θ). However, for energies E i >1 MeV, the sum has to be carried out with the help of a multiple convergence acceleration [57].…”

Section: Nsa Methods For Spin-zero Nucleimentioning

confidence: 99%

e^± Ar scattering in the energy range 1 eV ≤ E _i ≤ 0.5 GeV

Haque

Jakubaßa-Amundsen³

et al. 2019

J. Phys. Commun.

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A theoretical investigation on differential, integral, momentum transfer, viscosity cross sections and spin polarization for elastically scattered electrons and positrons from Ar atoms in the energy range 1 eVE i 0.5 GeV is presented. In addition, we have studied the critical minima in the elastic differential cross sections, and the absorption, total and ionization cross sections. Two different theoretical approaches, depending upon the incident energy, are employed for solving the relativistic Dirac equation with the partial-wave decomposition. The solution of the relativistic equation involves the use of either complex optical-model potentials or only nuclear potentials at higher energies. A comparison of the present results with the available experimental data and other theoretical findings produces a reasonable agreement throughout the investigated energy range.

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Section: Nsa Methods For Spin-zero Nucleimentioning

confidence: 99%

e^± Ar scattering in the energy range 1 eV ≤ E _i ≤ 0.5 GeV

Haque

Jakubaßa-Amundsen³

et al. 2019

J. Phys. Commun.

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“…2a for 64 Zn) but, as seen from Fig. 3, they also modulate the vacuum-polarization induced changes of S. In particular, dS shows oscillations with E kin in the same way as does S(V T ) which is displayed in [17] for 208 Pb. It should be noted, however, that dS as defined by (9) largely overestimates the influene of vacuum polarization if the diffraction effects lead to a spin asymmetry which approaches zero or changes sign.…”

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confidence: 58%

“…r→0 rU e (r) = 0. Numerical details are described in [17]. In calculating ψ V P we have disregarded any screening by the bound target electrons since such effects do not play a role at the high momentum transfers considered here.…”

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The influence of vacuum polarization on the Sherman function during elastic electron-nucleus scattering

Jakubassa-Amundsen

2014

Preprint

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“…The photoelectron spin polarization can be measured using Mott polarimetry [83][84][85]. The latter is based on the left-right asymmetry of Mott scattering cross section on a high-κ target.…”

Section: A Detection Of Photoelectronsmentioning

confidence: 99%

Above-threshold ionization with highly charged ions in superstrong laser fields. III. Spin effects and their dependence on laser polarization

2015

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Spin effects in the tunneling regime of strong-field ionization of hydrogenlike highly charged ions in linearly as well as circularly polarized laser fields are investigated. The impact of the polarization of a laser field on the spin effects is analyzed. Spin-resolved differential ionization rates are calculated employing the relativistic Coulombcorrected strong-field approximation developed in the previous paper of the series. Analytical expressions for spin asymmetries and the spin-flip probability, depending on the laser's polarization, are obtained for the photoelectron momentum corresponding to the maximum of the tunneling probability. A simple intuitive model is developed for the description of spin dynamics in tunnel ionization. The spin flip is shown to be experimentally observable by using moderate highly charged ions with a charge of the order of 20 and a laser field with an intensity of I ∼ 10 22 W/cm 2 .

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The Sherman function in highly relativistic elastic electron–atom scattering

Cited by 21 publications

References 41 publications

e^± Ar scattering in the energy range 1 eV ≤ E _i ≤ 0.5 GeV

e^± Ar scattering in the energy range 1 eV ≤ E _i ≤ 0.5 GeV

The influence of vacuum polarization on the Sherman function during elastic electron-nucleus scattering

Above-threshold ionization with highly charged ions in superstrong laser fields. III. Spin effects and their dependence on laser polarization

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The Sherman function in highly relativistic elastic electron–atom scattering

Cited by 21 publications

References 41 publications

e± Ar scattering in the energy range 1 eV ≤ E i ≤ 0.5 GeV

e± Ar scattering in the energy range 1 eV ≤ E i ≤ 0.5 GeV

The influence of vacuum polarization on the Sherman function during elastic electron-nucleus scattering

Above-threshold ionization with highly charged ions in superstrong laser fields. III. Spin effects and their dependence on laser polarization

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Product

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e^± Ar scattering in the energy range 1 eV ≤ E _i ≤ 0.5 GeV

e^± Ar scattering in the energy range 1 eV ≤ E _i ≤ 0.5 GeV