Stress-Biased Rearrangements and Preyield Behavior in Glasses

Patashinski, Alexander Z.; Moore, Jonathan D.; Bicerano, Jozef; Mudrich, Scott F.; Mazor, Michael H.; Ratner, Mark A.

doi:10.1021/jp0619484

Cited by 5 publications

(2 citation statements)

References 24 publications

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“…The similarly defined function for all atoms (including LLA) gives a description of the part of a configuration that keeps the local structure for a given time. To relate these internal microscopic characteristics to macroscopically observable quantities, one needs a micromechanical model of the material (an example of a micromechanical model for a stressed dynamically heterogeneous material can be found in ref 26). Construction and applications of appropriate micromechanical models to describe the response of the system to perturbations is an important but separate task that is beyond the scope of this Letter.…”

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confidence: 99%

Heterogeneous Structure, Heterogeneous Dynamics, and Complex Behavior in Two-Dimensional Liquids

Patashinski

Ratner

Grzybowski

et al. 2012

J. Phys. Chem. Lett.

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Analysis of the metrical and topological features of the local structure in a freezing two-dimensional Lennard-Jones system found that in a narrow strip [Formula: see text] of thermodynamic states close to the melting line, the liquid becomes a complex liquid characterized by a super-Arrhenius increase of relaxation times, stretched-exponential decay of correlations in time, and a power-law distribution of waiting times for changes in the local order. In [Formula: see text], the structure of the liquid and its dynamics are spatially heterogeneous; the sizes of ordered clusters are power-law distributed. Those features are governed by local structure evolution between solid-like and liquid-like (disordered) patterns. The liquid inside the strip [Formula: see text] gives a unique opportunity to study how heterogeneous structure, dynamics and complexity are intertwined with each other on a microscopic level.

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mentioning

confidence: 99%

Heterogeneous Structure, Heterogeneous Dynamics, and Complex Behavior in Two-Dimensional Liquids

Patashinski

Ratner

Grzybowski

et al. 2012

J. Phys. Chem. Lett.

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“…The viscoelastic behavior of systems with multiple relaxation times are still poorly understood with the fractional Maxwell model (FMM) approach showing some promise in describing the mathematical formalism , and the “sticky Rouse model” capturing many crucial physical details. , It should be noted that underlying reptation of entangled chains also influences the hydrogen bond relaxation time scales . Patashinski and co-workers recently proposed a new formalism to describe the yield-stress behavior in systems with a distribution of effective bond energies; we imagine that a similar approach can be used to describe the yield stress of HPMC HME due to the hydrogen bond network. Thus, the apparent yield stress would be a function of the temperature, the hydrogen bond energy distribution, the density of hydrogen bonds, and potentially even the applied external stress (see, e.g., ref ).…”

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confidence: 99%

Rheology of Cellulose Ether Excipients Designed for Hot Melt Extrusion

et al. 2018

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A new family of cellulosic ether polymeric excipients has been recently engineered for fabrication of amorphous solid dispersions of active pharmaceutical ingredients via hot-melt extrusion (HME). These hydroxypropyl methyl cellulose excipients enable plasticizer-free melt processing at much lower temperatures (135−160 °C) due to their substantially reduced glass transition temperatures (T g = 98−110 °C). The novel amorphous cellulose ethers were found to be rheologically solidlike well above their glass transition (T g + 70 °C). We demonstrate that in the pharmaceutically relevant HME processing temperature range these polymers behave similarly to yield-stress fluids and flow only when the applied stress exceeds a critical stress value. This critical stress value (0.50 ± 0.05 MPa, 150 °C) is surprisingly high but is easily achieved under typical HME conditions. The origin of their yield-stress fluidlike behavior is hypothesized to arise from hydrogen bonds of the HPMC materials that act as physical cross-links and do not relax within the measured temperature and time window unless the applied stress exceeds the critical stress value. Support for this hypothesis arises from infrared spectroscopic estimates of the free and bound hydrogen bond levels at end-use temperatures.

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