Breakdown of universal Lindemann criterion in the melting of Lennard-Jones polydisperse solids

Sarkar, Sarmistha; Jana, Chandramohan; Bagchi, Biman

doi:10.1007/s12039-017-1245-y

Cited by 17 publications

(7 citation statements)

References 40 publications

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“…In general, a critical Linderman index value, 0.1, is regarded as the melting indicator. 61 By viewing the radial distributions of the atomic Lindeman index (Fig. 10f and g), the particle surface atoms exhibit a higher Lindemann index, reaching 0.15 at 1800 K. The surface atoms have smaller coordination numbers and greater energies than the atoms in the interior regions of the particle.…”

Section: Resultsmentioning

confidence: 98%

Monitoring the melting behavior of boron nanoparticles using a neural network potential

Chang

Chu

Chen

2023

Phys. Chem. Chem. Phys.

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Section: Resultsmentioning

confidence: 98%

Monitoring the melting behavior of boron nanoparticles using a neural network potential

Chang

Chu

Chen

2023

Phys. Chem. Chem. Phys.

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“…This critical value saturates to a value of about 0.11 for all temperatures, in good agreement with the experimental value of 0.12. Further, it was shown that the Lindemann rule breaks down for polydisperse systems, 183 as the increased root-meansquare amplitude of the smaller particles plays a role in the segregation of them prior to melting, although melting itself remain discontinuous.…”

Section: General Aspectsmentioning

confidence: 99%

Melting Is Well-Known, but Is It Also Well-Understood?

de With

2023

Chem. Rev.

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Contrary to continuous phase transitions, where renormalization group theory provides a general framework, for discontinuous phase transitions such a framework seems to be absent. Although the thermodynamics of the latter type of transitions is wellknown and requires input from two phases, for melting a variety of one-phase theories and models based on solids has been proposed, as a generally accepted theory for liquids is (yet) missing. Each theory or model deals with a specific mechanism using typically one of the various defects (vacancies, interstitials, dislocations, interstitialcies) present in solids. Furthermore, recognizing that surfaces are often present, one distinguishes between mechanical or bulk melting and thermodynamic or surface-mediated melting. After providing the necessary preliminaries, we discuss both types of melting in relation to the various defects. Thereafter we deal with the effect of pressure on the melting process, followed by a discussion along the line of type of materials. Subsequently, some other aspects and approaches are dealt with. An attempt to put melting in perspective concludes this review.

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“…Consequently, simple melting "rules" formulated from experimental observation have been popular. The Lindemann melting criterion [13][14][15] is perhaps the most widely used melting rule, and it states that melting occurs when the root mean amplitude of vibration exceeds a threshold value in relation to the nearest neighbor distance (originally stated to be 10%). At melt, all atoms vibrate at the Einstein frequency so the equipartition theorem can be used to equate the amplitude of vibration to the temperature, yielding 𝑇 ( =…”

Section: Material-level Microscopic Descriptionmentioning

confidence: 99%

Phase change materials for thermal energy storage: A perspective on linking phonon physics to performance

Lilley

Menon

Kaur

et al. 2021

Journal of Applied Physics

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Thermal energy storage is being actively investigated for grid, industrial, and building applications for an all-renewable energy world. Phase change materials (PCMs), which are commonly used in thermal energy storage applications, are difficult to design because they require both excellent energy density and thermal transport, both of which are difficult to predict from simple physicsbased models. In this perspective, we describe recent advances in the understanding of the equilibrium and transport properties of PCM materials that can help accelerate technology development. We then emphasize how the microscopic phonon-picture of both liquids and solids enables better understanding and predictive power of novel PCM systems. We then show how this microscopic picture can be used to understand kinetic processes, such as supercooling, and how it can impact the thermal power output in thermal energy storage systems.

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Breakdown of universal Lindemann criterion in the melting of Lennard-Jones polydisperse solids

Cited by 17 publications

References 40 publications

Monitoring the melting behavior of boron nanoparticles using a neural network potential

Monitoring the melting behavior of boron nanoparticles using a neural network potential

Melting Is Well-Known, but Is It Also Well-Understood?

Phase change materials for thermal energy storage: A perspective on linking phonon physics to performance

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