Can the Lennard-Jones solid be expected to be fcc?

Waal, B.W. van de

doi:10.1103/physrevlett.67.3263

Cited by 72 publications

(45 citation statements)

References 13 publications

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“…The internal structure in new cluster regions built at the low temperature is characterized by many stacking faults resulting in the formation of fcc and hcp parallel layers [11]. This is caused by approximately the same binding energies for fcc and hcp structure, leading to an ambiguity in determining the position of newly added atoms on a close-packed layer [9]. Moreover, two hcp monolayers are often inclined one to each other at an acute angle close to α = 70.5° (see the hcp structure in Fig.…”

Section: Resultsmentioning

confidence: 99%

“…As predicted by van de Waal [8], the growth of an ideal fcc cluster would be complicated by difficulty in the formation of growth islands on the close packed (111) faces and possibility for wrong position of the islands resulting in the formation of hcp stacking faults [9]. Therefore, following his previous suggestion on the decisive role of lattice defects promoting the growth of the fcc structure [9], he proposed the defected fcc cluster composed of 3281 atoms [8] with "non-disappearing" fcc growth sites (here also called as the van de Waal cluster). The importance of defects in determining the fcc structure has been clearly observed recently [10] in case of the proposed LJ 3281 cluster, where, instead of energetically more preferred hcp structure, overgrowth of fcc structure takes place.…”

Section: Introductionmentioning

confidence: 99%

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Preference for fcc atom stacking observed during growth of defect‐free LJ₃₂₈₁ clusters

Polak

2007

Cryst. Res. Technol.

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Growth simulations of 3-dimensional Lennard-Jones (LJ) clusters/nuclei from the vapor phase were carried out in order to estimate the role of kinetic and energetic effects in determining the internal structure of the clusters. The simulated growth was realized from N = 3281 up to ca. 10000 atoms at two reduced growth temperatures T * = 0.3 and 0.5 and the vapor atom concentration n v = 0.002 (in reduced units of LJ system). During growth at the low temperature, clusters evolve from octahedral to an irregular shape, while at the higher one they become spherical. Statistics of newly created structural units shows a strong preference for the formation of fcc units with their number approximately 3-4 times larger than those of the hcp units. The possible explanation of this preference is by: (1) a larger surface diffusion leading to near spherical shape of clusters, (2) an energetic effect caused by different interaction energy of two fcc or hcp layers located on the neighboring {111} planes, and (3) an entropic effect in the form of disappearance of hcp island on the closepacked fcc layers.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Preference for fcc atom stacking observed during growth of defect‐free LJ₃₂₈₁ clusters

Polak

2007

Cryst. Res. Technol.

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“…We find that the hexagonal close-packed (hcp) and other stacking variants are considerably less stable than fcc at high pressures where fcc is more stable than bcc and the σ-phase. This result is remarkable since for the Lennard-Jones potential hcp is known to be slightly more stable than fcc [25].…”

Section: B Ground-state Structuresmentioning

confidence: 87%

Solid-phase structures of the Dzugutov pair potential

Roth

Denton

2000

Phys. Rev. E

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In recent computer simulations of a simple monatomic system interacting via the Dzugutov pair potential, freezing of the fluid into an equilibrium dodecagonal quasicrystal has been reported [M. Dzugutov, Phys. Rev. Lett. 70, 2924Lett. 70, (1993]. Here, using a combination of molecular dynamics simulation and thermodynamic perturbation theory, we conduct a detailed analysis of the relative stabilities of solid-phase structures of the Dzugutov-potential system. At low pressures, the most stable structure is found to be a bcc crystal, which gives way at higher pressures to an fcc crystal. Although a dodecagonal quasicrystal and a σ-phase crystal compete with the bcc crystal for stability, they remain always metastable.

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“…The atomic arrangement in this cluster is the same as that found in the crossing region of intersecting stacking faults in (otherwise perfect) fcc crystals. If such clusters are used as seeds for sequential building algorithms [13], they will not produce a glass but rather a (nearly perfect) fcc crystal, provided new atoms are placed in sites with fourfold coordination, rather than tetrahedral sites [14]. If loops, such as those visible in Fig.…”

Section: Extended Modelsmentioning

confidence: 99%

On the origin of second-peak splitting in the static structure factor of metallic glasses

Waal

1995

Journal of Non-Crystalline Solids

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It is proposed that the splitting of the second peak of the total static structure factor, S(k), of many metallic glasses is essentially the same feature as the indentation at ko-= (9/2)~r in the function (sin ko-+ cr 1 sin kacr), caused by the coincidence of the fourth minimum of the second term with the third maximum of the first term when a = 5/3. Together with the strong-weak relation of the split peak components of S(k), this feature indicates the splitting to be direct evidence for face-sharing of regular tetrahedra (a = 2~/2-/3 ) dominating the topological short range order; increasing the number of face-sharing tetrahedra in local structural units indeed increases the amount of peak splitting in S(k); a dense random packing of well defined identical structural units (DRPSU), with neighbouring units linked together by a shared icosahedron, is described in detail. The packing fraction in a homogeneous, isotropic 1078-atom model is 0.67, after static relaxation under a two-body Lennard-Jones potential.

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Can the Lennard-Jones solid be expected to be fcc?

Cited by 72 publications

References 13 publications

Preference for fcc atom stacking observed during growth of defect‐free LJ₃₂₈₁ clusters

Preference for fcc atom stacking observed during growth of defect‐free LJ₃₂₈₁ clusters

Solid-phase structures of the Dzugutov pair potential

On the origin of second-peak splitting in the static structure factor of metallic glasses

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Can the Lennard-Jones solid be expected to be fcc?

Cited by 72 publications

References 13 publications

Preference for fcc atom stacking observed during growth of defect‐free LJ3281 clusters

Preference for fcc atom stacking observed during growth of defect‐free LJ3281 clusters

Solid-phase structures of the Dzugutov pair potential

On the origin of second-peak splitting in the static structure factor of metallic glasses

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Preference for fcc atom stacking observed during growth of defect‐free LJ₃₂₈₁ clusters

Preference for fcc atom stacking observed during growth of defect‐free LJ₃₂₈₁ clusters