Quantum dynamic screening effects on the elastic collisions in strongly coupled semiclassical plasmas

Kim, Chang-Geun; Jung, Young-Dae

doi:10.1063/1.3674996

Cited by 16 publications

(11 citation statements)

References 14 publications

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“…Clearly, the static Debye-Hückel potential is reached as the collision velocity v → 0. This is a phenomenological and simple approach to trace the dynamic screening, but it grasps the essential of dynamic screening and has been used to study the elastic collisions [64]. Similar treatment is also applied to the polarization potential, Eq.…”

Section: Effects Of Many-particle Correlations and Dynamic Screeningmentioning

confidence: 98%

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Equations of state, transport properties, and compositions of argon plasma: Combination of self-consistent fluid variation theory and linear response theory

Quan

Chen

et al. 2015

Phys. Rev. E

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A consistent theoretical model that can be applied in a wide range of densities and temperatures is necessary for understanding the variation of a material's properties during compression and heating. Taking argon as an example, we show that the combination of self-consistent fluid variational theory and linear response theory is a promising route for studying warm dense matter. Following this route, the compositions, equations of state, and transport properties of argon plasma are calculated in a wide range of densities (0.001−20 g/cm 3 ) and temperatures (5−100 kK). The obtained equations of state and electrical conductivities are found in good agreement with available experimental data. The plasma phase transition of argon is observed at temperatures below 30 kK and density about 2−6 g/cm 3 . The minimum density for the metallization of argon is found to be about 5.8 g/cm 3 , occurring at 30−40 kK. The effects of many-particle correlations and dynamic screening on the electrical conductivity are also discussed through the effective potentials.

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Section: Effects Of Many-particle Correlations and Dynamic Screeningmentioning

confidence: 98%

“…This effective potential has been used to study the Coulomb Bremsstrahlung process [63] and the electron captures [64].…”

Section: Effects Of Many-particle Correlations and Dynamic Screeningmentioning

confidence: 99%

Equations of state, transport properties, and compositions of argon plasma: Combination of self-consistent fluid variation theory and linear response theory

Quan

Chen

et al. 2015

Phys. Rev. E

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“…In Ramazanov et al, the effective Ramazanov–Dzhumagulova–Omarbakiyeva (RDO) potential of electron–atom interaction was presented, considering the effects of static or dynamic screening and diffraction, as

Φ_{e a} ((), r) = prefix- \frac{α_{p} e^{2}}{2 r^{4} C} {(e^{- B r} (1 + B r) - e^{- A r} (1 + A r))}^{2},

where

A^{2} = ((), 1 + \sqrt{C}) true/ ((), 2 λ^{2})

B^{2} = ((), 1 - \sqrt{C}) true/ ((), 2 λ^{2})

C = 1 - 4 λ^{2} true/ r_{0}^{2}

r_{0} = r_{D} {(1 + υ^{2} / υ_{T h}^{2})}^{1 true/ 2}

, υ is the relative velocity of the colliding particles, υ Th = ( k B T / m e ) 1/2 is the thermal velocity, and r D = ( k B T /(8 πe 2 n e )) 1/2 is the Debye length. At small velocities of the colliding particles, r 0 tends to the static Debye length, and at high velocities potentials and take into account the effect of dynamic screening.…”

Section: Interaction Potentialsmentioning

confidence: 99%

“…where [33,34] is the relative velocity of the colliding particles, Th = (k B T/m e ) 1/2 is the thermal velocity, and r D = (k B T/(8 e 2 n e )) 1/2 is the Debye length. At small velocities of the colliding particles, r 0 tends to the static Debye length, and at high velocities potentials (1) and (2) take into account the effect of dynamic screening.…”

Section: Interaction Potentialsmentioning

confidence: 99%

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Optical reflectivity based on the effective interaction potentials of xenon plasma

Shalenov

Rosmej

Reinholz

et al. 2017

Contrib. Plasma Phys

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New results on the reflectivity and Brewster angle of dense xenon plasmas based on of the effective interaction potentials (which take into account static and dynamic screening effects) at pressures of 1.6–20 GPa and temperatures of ∼30,000 K are presented. Using Fresnel formulas, the reflectivity coefficients for the s‐ and p‐polarized laser waves are investigated. The influence of atoms, which was taken into account at the level of collision frequency via an effective interaction potential, is proven to be crucial for understanding the reflection process.

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Phase Shifts and Scattering Cross Sections of the Particles of Non‐ideal Semiclassical Plasmas Based on the Dynamic Interaction Potential

Dzhumagulova

Shalenov

Ramazanov

et al. 2015

Contrib. Plasma Phys.

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Quantum dynamic screening effects on the elastic collisions in strongly coupled semiclassical plasmas

Cited by 16 publications

References 14 publications

Equations of state, transport properties, and compositions of argon plasma: Combination of self-consistent fluid variation theory and linear response theory

Equations of state, transport properties, and compositions of argon plasma: Combination of self-consistent fluid variation theory and linear response theory

Optical reflectivity based on the effective interaction potentials of xenon plasma

Phase Shifts and Scattering Cross Sections of the Particles of Non‐ideal Semiclassical Plasmas Based on the Dynamic Interaction Potential

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