Experimental validation of interpolation method for pair correlations in model crystals

Yakovlev, Egor V.; Chaudhuri, M.; Kryuchkov, Nikita P.; Ovcharov, Pavel V.; Sapelkin, Andrei V.; Yurchenko, Stanislav O.

doi:10.1063/1.5116176

Cited by 14 publications

(7 citation statements)

References 117 publications

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“…For silica particles in deionised water, under the same experimental conditions as we had, κσ = σ/λ D ≈ 25.8, as was obtained in Ref. [72].…”

Section: Details Of MD Simulationssupporting

confidence: 56%

“…The same framework, as we proposed it here, is also suitable for studies of 3D systems. However, gravitationally-compensated colloidal systems [72] and the spatial hodographs of rotating electric field [60] should be used instead of the in-plane rotating field, to create isotropic tunable interactions. The system should be imaged in bulk, and the same methodology as we propose here, can be applied.…”

Section: Discussionmentioning

confidence: 99%

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2D colloids in rotating electric fields: A laboratory of strong tunable three-body interactions

Yakovlev

Kryuchkov

Korsakova

et al. 2022

Journal of Colloid and Interface Science

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“…For silica particles in deionised water, under the same experimental conditions as we had, κσ = σ/λ D ≈ 25.8, as was obtained in Ref. [72].…”

Section: Details Of MD Simulationssupporting

confidence: 56%

Section: Discussionmentioning

confidence: 99%

2D colloids in rotating electric fields: A laboratory of strong tunable three-body interactions

Yakovlev

Kryuchkov

Korsakova

et al. 2022

Journal of Colloid and Interface Science

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“…The role of attraction can be tested experimentally in colloidal systems, known for a long time as model systems demonstrating a wide range of "molecularlike" phenomena 1,[47][48][49][50] , in particular, crystallization and melting [51][52][53][54][55][56][57][58][59] , solid-solid phase transitions [60][61][62] , condensation and critical phenomena [63][64][65] caused by relatively short-range attractive depletion forces 66 . These collective phenomena can be visualized in real-time with spatial resolution of individual particles.…”

Section: Introductionmentioning

confidence: 99%

The role of attraction in the phase diagrams and melting scenarios of generalized 2D Lennard-Jones systems

Tsiok,

Fomin,

Gaiduk

et al. 2021

Preprint

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Monolayer and two-dimensional (2D) systems exhibit rich phase behavior, compared with 3D systems, in particular, due to the hexatic phase playing a central role in melting scenarios. The attraction range is known to affect critical gas-liquid behavior (liquid-liquid in protein and colloidal systems), but the effect of attraction on melting in 2D systems remains unstudied systematically. Here, we reveal how the attraction range affects the phase diagrams and melting scenarios in a 2D system. Using molecular dynamics simulations we considered the generalized Lennard-Jones system with a fixed repulsion branch and different power indices of attraction, from long-range dipolar to short-range sticky-spheres-like. A drop in the attraction range has been found to reduce the temperature of the gas-liquid critical point, bringing it closer to the gas-liquid-solid triple point. At high-temperatures, attraction does not affect the melting scenario that proceeds through the cascade of solid-hexatic (Berezinski-Kosterlitz-Thouless) and hexatic-liquid (first-order) phase transitions. In the case of dipolar attraction, we observed two triple points, inherent in a 2D system: hexatic-liquid-gas and crystal-hexatic-gas, the temperature of the crystal-hexatic-gas triple point is below the hexatic-liquid-gas triple point. This observation may have far-reaching consequences for future studies, since phase diagrams determine possible routes of self-assembly in molecular, protein, and colloidal systems, whereas the attraction range can be adjusted with complex solvents and external electric or magnetic fields. The results obtained may be widely used in condensed matter, chemical physics, materials science, and soft matter.

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“…In order to observe mode anticrossing directly, we performed dedicated experiments with 2D system of charged microparticles in the same manner as described previously. [32][33][34][35][36] To prepare the fluid, we melted 2D complex plasma crystal utilising the mode-coupling instability [36][37][38] (see details in SI 31 ), however, the same could be done using laser heating. 39,40 First, the model fluid system was set up.…”

mentioning

confidence: 99%

“…(The latter is also described in detail in the Supporting Information (SI).) To observe mode anticrossing directly, we performed dedicated experiments with a 2D system of charged microparticles in the same manner as previously described. − To prepare the fluid, we melted a 2D complex plasma crystal utilizing the mode-coupling instability − (see details in the SI); however, the same could be done using laser heating. , …”

mentioning

confidence: 99%

Direct Experimental Evidence of Longitudinal and Transverse Mode Hybridization and Anticrossing in Simple Model Fluids

Yakovlev

Kryuchkov

Ovcharov

et al. 2020

J. Phys. Chem. Lett.

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A significant number of key properties of condensed matter are determined by the spectra of elementary excitations and, in particular-collective vibrations. However, behaviour and description of collective modes in disordered media (e.g. liquids and glasses) remains a challenging area of modern condensed matter science. Recently, anticrossing between longitudinal and transverse modes was predicted theoretically and observed in molecular dynamics simulations, but this fundamental phenomenon has never been observed experimentally. Here, we demonstrate the mode anticrossing in a simple Yukawa fluid constructed from charged microparticles in weakly-ionized gas. Theory, simulations, and experiments show clear evidence of mode anticrossing that is accompanied by mode hybridization and strong redistribution of the excitation spectra. Our results provide significant advance in understanding excitations of fluids, opening new prospectives for studies of dynamics, thermodynamics, and transport phenomena in a wide variety of systems from noble gas fluids and metallic melts to strongly coupled plasmas, molecular, and complex fluids.

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Experimental validation of interpolation method for pair correlations in model crystals

Cited by 14 publications

References 117 publications

2D colloids in rotating electric fields: A laboratory of strong tunable three-body interactions

2D colloids in rotating electric fields: A laboratory of strong tunable three-body interactions

The role of attraction in the phase diagrams and melting scenarios of generalized 2D Lennard-Jones systems

Direct Experimental Evidence of Longitudinal and Transverse Mode Hybridization and Anticrossing in Simple Model Fluids

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