Unified description of sound velocities in strongly coupled Yukawa systems of different spatial dimensionality

2020

Phys. Rev. Research

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It is demonstrated that the Lindemann's criterion of melting can be formulated for twodimensional classical solids using statistical mechanics arguments. With this formulation the expressions for the melting temperature are equivalent in three and two dimensions. Moreover, in two dimensions the Lindemann's melting criterion essentially coincides with the Berezinskii-Kosterlitz-Thouless-Halperin-Nelson-Young melting condition of dislocation unbinding.

mentioning

confidence: 94%

“…Taking into account the strong inequality c 2 l ≫ c 2 t (which holds in both 2D and 3D soft interacting particle systems [45][46][47]) we arrive at the 2D melting conditions…”

mentioning

confidence: 99%

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Lindemann melting criterion in two dimensions

2020

Phys. Rev. Research

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“…Recently, a unified description of elastic moduli of strongly coupled Yukawa systems of different spatial dimensionality has been proposed (main results are expressed in terms of the longitudinal and transverse sound velocities, directly related to elastic moduli). 60 In this approximation the elastic moduli are related to the internal energy of Yukawa solids using relatively weak sensitivity of the RDFs to the screening parameter at weak screening and the fact that the internal energy is dominated by the static contribution. The excess contribution to the instantaneous shear modulus is then expressed in terms of Madelung constant and its first two derivatives with respect to κ (for details see Ref.…”

mentioning

confidence: 99%

“…The excess contribution to the instantaneous shear modulus is then expressed in terms of Madelung constant and its first two derivatives with respect to κ (for details see Ref. 60). Using the ion sphere model 61,62 as a proxi for the Madelung constant the following expression can be derived 60…”

mentioning

confidence: 99%

Instantaneous shear modulus of Yukawa fluids across coupling regimes

Klumov

2020

Physics of Plasmas

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The high frequency (instantaneous) shear modulus of three-dimensional Yukawa systems is evaluated in a wide parameter range, from the very weakly coupled gaseous state to the strongly coupled fluid at the crystallization point (Yukwa melt). This allows us to quantify how shear rigidity develops with increasing coupling and inter-particle correlations. The radial distribution functions (RDFs) needed to calculate the excess shear modulus have been obtained from extensive molecular dynamics (MD) simulations. MD results demonstrate that fluid RDFs appear quasi-universal on the curves parallel to the melting line of a Yukawa solid, in accordance with the isomorph theory of Roskilde-simple systems. This quasi-universality, allows to simplify considerably calculations of quantities involving integrals of the RDF (elastic moduli represent just one relevant example). The calculated reduced shear modulus grows linearly with the coupling parameter at weak coupling and approaches a quasi-constant asymptote at strong coupling. The asymptotic value at strong coupling is in reasonably good agreement with the existing theoretical approximation.

Onset of transverse (shear) waves in strongly-coupled Yukawa fluids

The Journal of Chemical Physics

Kryuchkov

et al. 2019

A simple practical approach to describe transverse (shear) waves in strongly-coupled Yukawa fluids is presented. Theoretical dispersion curves, based on hydrodynamic consideration, are shown to compare favorably with existing numerical results for plasma-related systems in the long-wavelength regime. The existence of a minimum wave number below which shear waves cannot propagate and its magnitude are properly accounted in the approach. The relevance of the approach beyond plasma-related Yukawa fluids is demonstrated by using experimental data on transverse excitations in liquid metals Fe, Cu, and Zn, obtained from inelastic x-ray scattering. Some potentially important relations, scalings, and quasi-universalities are discussed. The results should be interesting for a broad community in chemical physics, materials physics, physics of fluids and glassy state, complex (dusty) plasmas, and soft matter.