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

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

doi:10.1021/acs.jpclett.9b03568

Cited by 14 publications

(12 citation statements)

References 65 publications

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“…Experimentally, excitation spectra in fluids can be obtained with inelastic neutron and x-ray scattering [9][10][11][12][13][14][15][16][17]. Yet another approach is to use complex plasmas -the model systems of charged and strongly-interacting particles levitating in a weakly-ionized gas, whose interactions can be tuned, and the motions can be visualized [18][19][20][21]. Molecular dynamics (MD) simulations are also widely used [17,[22][23][24][25][26][27][28][29][30][31][32][33][34] to study collective dynamics in systems with a range of interatomic interactions and, crucially, allow access to a broad range of parameters, including the ones that may not be accessible experimentally.…”

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confidence: 99%

“…The value of q-gap (characterizing transverse excitations at small q) has been assumed [30,41,42] to influence the heat capacity of fluids, but this has never been tested directly in either experiments or MD simulations. Another generic phenomenon recently studied with MD simulations, theoretically, and experimentally with the model fluids [21,43] is anticrossing of longitudinal and transverse excitations. It has been demonstrated that structural disorder and ahnarmonicity induce mutual mixing of the modes at large q.…”

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confidence: 99%

“…S1 in SM [52]). However, the difference becomes apparent at qn −1/3 /π > 1 corresponding to the region of mode anticrossing [21,43] and is a consequence of formation of hybridized low-and high-frequency modes (red circles) instead of the crossed dispersion curves (grey triangles). The high-frequency mode, associated with longitudinal (sound) excitations at small q, behaves as ω h (q) ∝ √ T q at large q [9,32,43,54] and, beginning from some temperature, the high-frequency dispersion curve transforms from oscillating form (with sign-changing group velocity v g = ∂ω h /∂q, inherent for solids) to gas-like dispersion with v g > 0 at all q.…”

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confidence: 99%

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Universal Effect of Excitation Dispersion on the Heat Capacity and Gapped States in Fluids

et al. 2020

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The change in dispersion of high-frequency excitations in fluids, from oscillating solid-like to monotonous gas-like one, is shown for the first time to affect thermal behavior of heat capacity and the q-gap width in reciprocal space. With in silico study of liquified nobel gases, liquid iron, liquid mercury, and model fluids, we established universal bilinear dependence of heat capacity on q-gap width, whereas the crossover precisely corresponds to the change in the excitation spectra. The results open novel prospects for studies of various fluids, from simple to molecular liquids and melts.

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Universal Effect of Excitation Dispersion on the Heat Capacity and Gapped States in Fluids

et al. 2020

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“…2(a) and 2(d) behave similarly to those reported in Refs. [31,[38][39][40]. In the long-wavelength limit, as usual, these branches are attributed to the longitudinal and transverse collective modes [31,40].…”

Section: Resultsmentioning

confidence: 76%

“…The excitation spectra were obtained using the procedures described in Refs. [31,[37][38][39][40]. First, we calculated the velocity current spectra [31,41]:…”

Section: MD Simulationsmentioning

confidence: 99%

From soft- to hard-sphere fluids: Crossover evidenced by high-frequency elastic moduli

et al. 2021

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The conventional (Zwanzig-Mountain) expressions for instantaneous elastic moduli of simple fluids predict their divergence as the limit of hard-sphere (HS) interaction is approached. However, elastic moduli of a true HS fluid are finite. Here we demonstrate that this paradox reveals the soft-to-hard-sphere crossover in fluid excitations and thermodynamics. With extensive in silico study of fluids with repulsive power-law interactions (∝ r −n ), we locate the crossover at n 10-20 and develop a simple and accurate model for the HS regime. The results open prospects to deal with the elasticity and related phenomena in various systems, from simple fluids to melts and glasses.

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Emergence of Debye Scaling in the Density of States of Liquids under Nanoconfinement

Yu,

Jin,

Fan

et al. 2024

ACS Nano

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In the realm of nanoscience, the dynamic behaviors of liquids at scales beyond the conventional structural relaxation time, τ, unfold a fascinating blend of solid-like characteristics, including the propagation of collective shear waves and the emergence of elasticity. However, in classical bulk liquids, where τ is typically of the order of 1 ps or less, this solid-like behavior remains elusive in the low-frequency region of the density of states (DOS). Here, we provide evidence for the emergent solid-like nature of liquids at short distances through inelastic neutron scattering measurements of the low-frequency DOS in liquid water and glycerol confined within graphene oxide membranes. In particular, upon increasing the strength of confinement, we observe a transition from a liquid-like DOS (linear in the frequency ω) to a solid-like behavior (Debye law, ∼ω2) in the range of 1–4 meV. Molecular dynamics simulations confirm these findings and reveal additional solid-like features, including propagating collective shear waves and a reduction in the self-diffusion constant. Finally, we show that the onset of solid-like dynamics is pushed toward low frequency along with the slowing-down of the relaxation processes upon confinement. This nanoconfinement-induced transition, aligning with k-gap theory, underscores the potential of leveraging liquid nanoconfinement in advancing nanoscale science and technology, building more connections between fluid dynamics and materials engineering.

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

Cited by 14 publications

References 65 publications

Universal Effect of Excitation Dispersion on the Heat Capacity and Gapped States in Fluids

Universal Effect of Excitation Dispersion on the Heat Capacity and Gapped States in Fluids

From soft- to hard-sphere fluids: Crossover evidenced by high-frequency elastic moduli

Emergence of Debye Scaling in the Density of States of Liquids under Nanoconfinement

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