Experimental evidence of mosaic structure in strongly supercooled molecular liquids

Caporaletti, Federico; Capaccioli, S.; Valenti, Sofia; Mikolasek, Mirko; Chumakov, A. I.; Monaco, G.

doi:10.1038/s41467-021-22154-8

Cited by 26 publications

(19 citation statements)

References 44 publications

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“…Similar sudden and hardly predictable re-arrangements have been found in simulations of active Ornstein-Uhlenberg particles [55], sheared granular media [56] and in epithelial tissues [34]. Interestingly, the string-like cooperative motion of particles in a closeto glassy state were observed in super-cooled liquids [57,58], simulations of Lennart-Jones mixtures [59] and granular beads [60].…”

Section: Dynamic Heterogeneity Due To the Co-existence Of Locally Ent...supporting

confidence: 65%

Chloroplasts in plant cells show active glassy behavior under low light conditions

Schramma

Israëls

Jalaal

2022

Preprint

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Plants have developed intricate mechanisms to adapt to changing light conditions. Besides photo- and heliotropism - the differential growth towards light and the diurnal motion with respect to sunlight - chloroplast motion acts as a fast mechanism to change the intracellular structure of leaf cells. While chloroplasts move towards the sides of the plant cell to avoid strong light, they accumulate and spread out into a layer on the bottom of the cell at low light to increase the light absorption efficiency. Although the motion of chloroplasts has been studied for over a century, the collective organelle-motion leading to light adapting self-organized structures remains elusive. Here we study the active motion of chloroplasts under dim light conditions, leading to an accumulation in a densely packed quasi-2D layer. We observe burst-like re-arrangements and show that these dynamics resemble colloidal systems close to the glass transition by tracking individual chloroplasts. Furthermore, we provide a minimal mathematical model to uncover relevant system parameters controlling the stability of the dense configuration of chloroplasts. Our study suggests that the meta-stable caging close to the glass-transition in the chloroplast mono-layer serves a physiological relevance. Chloroplasts remain in a spread-out configuration to increase the light uptake, but can easily fluidize when the activity is increased to efficiently re-arrange the structure towards an avoidance state. Our research opens new questions about the role that dynamical phase transitions could play in self-organized intracellular responses of plant cells towards environmental cues.

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Section: Dynamic Heterogeneity Due To the Co-existence Of Locally Ent...supporting

confidence: 65%

Chloroplasts in plant cells show active glassy behavior under low light conditions

Schramma

Israëls

Jalaal

2022

Preprint

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“…This view is recently justified in ref . using the microscopic data from nuclear γ-resonance time-domain-interferometry experiments. − …”

Section: Resultsmentioning

confidence: 99%

Sub-Rouse Dynamics in Poly(isobutylene) as a Function of Molar Mass

et al. 2021

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We report on the molar mass dependence of the segmental, sub-Rouse, and terminal relaxation processes of poly(isobutylene). For this purpose, seven samples were synthesized with molar masses in the range from 2.8 to 172 kg·mol–1 and investigated by temperature-modulated differential scanning calorimetry, dielectric spectroscopy, and rheology. Rheology provided access to the terminal times that were found to scale as τterm ∼ Μ 3.2. On the other hand, the sub-Rouse dielectric process shows a very weak molar mass dependence (τsub – Rouse/τSM ∼ M 0.1), that is, distinctly different from the Rouse and terminal dynamics. We infer that the sub-Rouse mode has a lengthscale intermediate to the statistical segment length (∼1.25 nm) and the length of an entanglement strand (∼2.3 nm).

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“…Another example indicating the imperative importance of the length scale dependence study is the reported crossover from microscopic dynamics dominated by the slow α-relaxation, to the Johari-Goldstein (JG) β-relaxation at a certain length scale as the temperature is decreased in the intermediate supercooled liquid region. Via neutron spin-echo (NSE) 18 – 20 and nuclear resonance X-ray scattering (NRXS) 21 – 23 , this slow α and JG β crossover which occurrs in the time scale of ≈10 ns to ≈10 3 ns has been directly observed, and its occurrence has been found to be wavevector ( Q )-dependent. This crossover occurs in the Q -range of the first minimum above the primary peak of the structure factor S ( Q ), but around the primary peak it is either not observed 21 , 22 or is too weak to be appreciated 23 , due to the local length scale of the JG β-process.…”

Section: Introductionmentioning

confidence: 99%

“…Via neutron spin-echo (NSE) 18 – 20 and nuclear resonance X-ray scattering (NRXS) 21 – 23 , this slow α and JG β crossover which occurrs in the time scale of ≈10 ns to ≈10 3 ns has been directly observed, and its occurrence has been found to be wavevector ( Q )-dependent. This crossover occurs in the Q -range of the first minimum above the primary peak of the structure factor S ( Q ), but around the primary peak it is either not observed 21 , 22 or is too weak to be appreciated 23 , due to the local length scale of the JG β-process. The technique of NSE, which encodes the dynamic signal in the spin of the neutrons and measures the Q -dependent intermediate scattering function (ISF) directly in time domain, offers the highest energy resolution among all neutron spectroscopy techniques and thus has been extensively employed for studying the relaxation dynamics of a wide variety of materials on the pico- to nanosecond time scale 19 , 24 – 36 .…”

Section: Introductionmentioning

confidence: 99%

Q-dependent collective relaxation dynamics of glass-forming liquid Ca0.4K0.6(NO3)1.4 investigated by wide-angle neutron spin-echo

et al. 2022

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The relaxation behavior of glass formers exhibits spatial heterogeneity and dramatically changes upon cooling towards the glass transition. However, the underlying mechanisms of the dynamics at different microscopic length scales are not fully understood. Employing the recently developed wide-angle neutron spin-echo spectroscopy technique, we measured the Q-dependent coherent intermediate scattering function of a prototypical ionic glass former Ca0.4K0.6(NO3)1.4, in the highly viscous liquid state. In contrast to the structure modulated dynamics for Q < 2.4 Å−1, i.e., at and below the structure factor main peak, for Q > 2.4 Å−1, beyond the first minimum above the structure factor main peak, the stretching exponent exhibits no temperature dependence and concomitantly the relaxation time shows smaller deviations from Arrhenius behavior. This finding indicates a change in the dominant relaxation mechanisms around a characteristic length of 2π/(2.4 Å−1) ≈ 2.6 Å, below which the relaxation process exhibits a temperature independent distribution and more Arrhenius-like behavior.

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Experimental evidence of mosaic structure in strongly supercooled molecular liquids

Cited by 26 publications

References 44 publications

Chloroplasts in plant cells show active glassy behavior under low light conditions

Chloroplasts in plant cells show active glassy behavior under low light conditions

Sub-Rouse Dynamics in Poly(isobutylene) as a Function of Molar Mass

Q-dependent collective relaxation dynamics of glass-forming liquid Ca0.4K0.6(NO3)1.4 investigated by wide-angle neutron spin-echo

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