Self-diffusion in liquid copper as seen by quasielastic neutron scattering

Meyer, Andreas

doi:10.1103/physrevb.81.012102

Cited by 102 publications

(98 citation statements)

References 18 publications

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“…In [36] (on page 3652) S m was taken as 2.8k, S f is taken from [6] and d derived from the density of liquids reported in [6]; the obtained D 0 is compared with those reported in [6,14,16,19] in Figure 2. It is seen that the calculated and the reported D 0 are comparable in order of magnitude.…”

Section: Calculation Of Dmentioning

confidence: 99%

“…Q SD~Em . Iida&Guthrie (compiled) [6] Meyer (QENS) [14,16] Demmel et al (QENS) [19] Chathoth et al (QENS) [38] Itami et al (microgravity) [9,39] Li Q SD =E m /2 Fig. 4.…”

Section: Estimation Of Q Sdmentioning

confidence: 99%

“…Besides measurements under microgravity, quasielastic neutron scattering (QENS) [14][15][16][17][18][19] was argued to probe "the dynamics on atomic length scales and on a picosecond time scale, short enough to be undisturbed by the presence of convective flow." [18] "In order to derive the self-diffusion coefficient from QENS one has to assume that concepts developed in the framework of hydrodyanmics [20], i.e.…”

Section: Present Knowledge On Self-diffusion Of Liquid Metalsmentioning

confidence: 99%

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Atomistics of self-diffusion in liquid metals

Wang

2017

EPJ Web Conf.

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Abstract. Self-diffusion in liquids is not well understood because of the lack of a clear microscopic knowledge on liquids. Here, on basis of an atomic model for liquids that we concluded from crystal melting, possible atomic details of self-diffusion in liquid metals are proposed. Accordingly, the coefficient of self-diffusion is derived for liquid elements, in reasonable agreement with experimental data.

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Section: Calculation Of Dmentioning

confidence: 99%

“…Q SD~Em . Iida&Guthrie (compiled) [6] Meyer (QENS) [14,16] Demmel et al (QENS) [19] Chathoth et al (QENS) [38] Itami et al (microgravity) [9,39] Li Q SD =E m /2 Fig. 4.…”

Section: Estimation Of Q Sdmentioning

confidence: 99%

Section: Present Knowledge On Self-diffusion Of Liquid Metalsmentioning

confidence: 99%

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Atomistics of self-diffusion in liquid metals

Wang

2017

EPJ Web Conf.

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“…As revealed in Table I, our calculated self-diffusion coefficients and viscosity of liquids at melting points are in agreement with available experimental data and other calculations. 4,[33][34][35][36][37] The self-diffusion coefficients and viscosity of liquids along the melting curve are presented in Figure 2, parts a and b, as a function of the pressure. Contrary to a large enhancement in the viscosity by 5∼12 orders of magnitude from ambient to Earth's pressure, 2 the self-diffusion coefficients and viscosity of liquids increase slightly with increasing pressure along the melting curves, which is consistent with the predication of the Andrade's model.…”

confidence: 99%

Entropy and transport properties of liquid metals along the melting curve

et al. 2017

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Molecular dynamics simulations are performed for several monatomic metals and Fe0.9Ni0.1 metallic alloy to study the transport properties and entropy of liquids along melting curve. Our results show that the self-diffusion coefficients and viscosity of liquids increase with increasing pressure along the melting curves. Analysis suggests that, at high pressure conditions, the pair correlation entropy S2 of liquids along melting curve is bout −3.71kB, independent of the pressure and variety of liquids, which indicates that there is no obvious change in liquid structure along the melting curve. The Rosenfeld entropy-scaling laws with S2 = −3.71kB and the special values of scaling parameters can give reasonable estimates for the self-diffusion coefficients and viscosity of liquid metals along melting curves. The effect of pressure on transport coefficients can be quantified through its corresponding effect on the melting temperature and number density, and this result is in consistent with the Andrade’s model. In addition, the variation of S2 provides a useful, experimentally accessible, structure-based criterion for freezing of liquid metals.

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“…Experimentally, the results for diffusion coefficients in liquid metals usually show deviations up to 100% (Banish and Lyle, 1999). According to Meyer (2010), SDCs are normally overestimated in the range of 10% -100% and also their temperature dependence deviates from the actual value without convection. It is also well known in the literature that the use of different potential functions gives slightly varying results for the self-diffusion coefficient, and the data for liquid metals are scarce and contains large errors (Merher, 2007;Ju et al, 2013).…”

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confidence: 99%

Temperature dependence of Self-diffusion coefficient (SDC) of liquid aluminum using Embedded Atom Method-Finnis-Sinclair (EAMFS) potential

Nenuwe¹,

Osafile²

2018

Journal of Applied Sciences and Environmental Management

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Atomistix tool kit force field calculations have been done, using the embedded atom method-FinnisSinclair potential as implemented in Virtual Nano Lab-Atomistix Tool Kit (VNL-ATK) to study the temperature dependence of self-diffusion coefficient of liquid aluminum. Also, we calculated the shear viscosity from the SutherlandEinstein relation, and reports that, the calculated SDC and viscosity are sensitive to temperature. Results obtained at 980, 1020 and 1060K for SDC underestimated available experimental results, while the calculated results for viscosity at 1000 and 1200K overestimated experimental data available in the literature. The underestimation might be due to the shortrange order in liquid Al. Keywords: self-diffusion, viscosity, aluminum, temperature.The thermophysical property of self-diffusion plays a significant role in metallurgical processes and solidification. Therefore, the knowledge of accurate self-diffusion coefficient is thus crucial for atomistic simulation methods and refining casting techniques for the synthesis of new materials (Kurz and Fisher, 1986;Sandro and Zach, 2017). Experimentally, the results for diffusion coefficients in liquid metals usually show deviations up to 100% (Banish and Lyle, 1999). According to Meyer (2010), SDCs are normally overestimated in the range of 10% -100% and also their temperature dependence deviates from the actual value without convection. It is also well known in the literature that the use of different potential functions gives slightly varying results for the self-diffusion coefficient, and the data for liquid metals are scarce and contains large errors (Merher, 2007;Ju et al., 2013). However, Ju et al., (2013), in their work, did a study of self-diffusion coefficients for liquid metals (Cu and Al) by using the embedded atom method (EAM) potential function. The results of self-diffusion coefficient for liquid copper and aluminum show inverse square relationship between the natural logarithm of self-diffusion coefficients and temperature and that diffusion coefficient increases with temperature. Their results for Cu and Al are in close agreement with results simulated by MKBA1 that are close to experimental values (Kargl et al., 2013). Also, Cherne and Deymier (2001), studied the shear viscosity and SDC of liquid aluminum (Al) by using the Equilibrium Molecular Dynamics (MD) and Non-Equilibrium Molecular Dynamics with the EAM potential function. Their results agree with the Sutherland-Einstein model, but the temperature dependence disagrees with the universal scaling law (Dzugutov, 1996). In a recent experimental work by Kargl et al., (2013), they did a measurement of selfdiffusion coefficient of liquid Al by the incoherent Quasielastic Neutron Scattering (QNS) at different temperatures and found that the aluminum SDCs also increased with temperature and follow the Arrhenius law with activation energy of 280±70 meV. Noel and Alain (2013), in their work, did a study of dynamic properties of liquid aluminum using DFT within LDA and GGA appr...

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Self-diffusion in liquid copper as seen by quasielastic neutron scattering

Cited by 102 publications

References 18 publications

Atomistics of self-diffusion in liquid metals

Atomistics of self-diffusion in liquid metals

Entropy and transport properties of liquid metals along the melting curve

Temperature dependence of Self-diffusion coefficient (SDC) of liquid aluminum using Embedded Atom Method-Finnis-Sinclair (EAMFS) potential

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