Toward a unified view of stress in small-molecular and in macromolecular liquids

Picu, Catalin R.; Loriot, G. B.; Weiner, J. H.

doi:10.1063/1.478351

Cited by 20 publications

(47 citation statements)

References 22 publications

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“…Thus, viscoelasticity will contain very valuable information concerning the rigidity of dense liquids close to a glass transition. For organic glasses, there are some early works concerning the study of flexible and rigid polymer models and how this is related with relaxation (Bartenev, 1970;Picu and Weiner, 1998;Picu et al, 1999). For inorganic glasses, this area is still open in many important aspects (Scopigno et al, 2007;Gueguen et al, 2015;Zhou et al, 2017;Zhu et al, 2018;Sen et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

Testing Rigidity Transitions in Glass and Crystal Forming Dense Liquids: Viscoelasticity and Dynamical Gaps

Toledo-Marín

Naumis

2019

Front. Mater.

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A computational study of rigidity for dense fluids of monodisperse and bidisperse hard-disks near a phase and a glass transition respectively is presented. To achieve this goal, the transversal part of the dynamical structure factor is calculated. In both cases, a viscoelastic behavior is obtained, with a dynamical gap determined by a critical wavevector k c. Transversal waves exist for k > k c while the maximal correlations happens at frequency ω = 0 for k < k c. In both cases k c goes to zero as the freezing point is approached. Both systems are able to fulfill a scaled dynamical law as a power law is found for the critical k c as a function of the packing. The obtained results indicate that this method gives an alternative to study rigidity and constraint theory in dense fluids, since it is possible to assign a number of floppy modes or broken constraints in the liquid by computing the number of modes below k c , as well as an effective average coordination number. Also, this suggests that the critical wavevector k c can serve as a suitable order parameter.

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Section: Introductionmentioning

confidence: 99%

Testing Rigidity Transitions in Glass and Crystal Forming Dense Liquids: Viscoelasticity and Dynamical Gaps

Toledo-Marín

Naumis

2019

Front. Mater.

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“…A comparison of these two approaches has been presented previously 11. The fundamental difference between our approach and that of applying stress or bias to the chain ends has also been discussed by Picu et al15 In either case, an important outcome of such oriented, nonequilibrium simulations is a direction‐dependent quantity, akin to a persistence length of the polymer, that depends on not only the stiffness of the chain but also the state of flow; it turns out to be a rapidly convergent function of the simulated oligomer size. After presenting the forward mapping, we describe a method for the potentially more useful “reverse” mapping, in which a local 〈 P 2 〉 is mapped to an observed 〈 QQ 〉, for example, from a process simulation.…”

Section: Introductionmentioning

confidence: 83%

Estimation of Macromolecular Configurational Properties from Atomistic Simulations of Oligomers under Nonequilibrium Conditions

Bernardin

2008

Macro Theory & Simulations

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Multi‐scale modeling requires the selection and preservation of information crucial to understanding the behavior of a system at appropriate length and time scales. For a full description of processed polymers, such a model must successfully link rheological properties with atomic‐level structure. We propose a method for the calculation of an important rheological state descriptor, the polymeric configuration tensor 〈QQ〉, from atomistic simulations of oligomers. The method requires no adjustable parameters and can describe anisotropic polymer conformations at conditions of significant deformation. We establish the validity of the atomistic‐to‐macromolecular scaling by comparing the consistency of predictions of 〈QQ〉 among different polyethylene oligomer systems. We use this method with the previously reported semi‐grand canonical Monte Carlo method to deduce macromolecular and atomic‐level structural information interchangeably for systems with flow‐induced orientation.magnified image

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“…The intrinsic stress is a cylindrical tensor in which the only nonzero components are 〈〈σ 11 〉〉 and 〈〈σ 22 〉〉 = 〈〈σ 33 〉〉. Most remarkably, it was observed that, when computed from atoms which are not at the chain ends, its components are independent of chain length , Since the intrinsic stress is directly related to the global stress t ij through eq 10 and 11, its invariance with respect to deformation and chain length suggests that it can be used to great advantage in describing stress production and relaxation.…”

Section: Intrinsic Stressesmentioning

confidence: 99%

“…The inability of the molecular picture of stress production to account for a number of effects such as the behavior of small molecular systems and the high-frequency response, , stimulated the development of an atomic-level description. − In this new framework, stress is computed on the atomic level by explicitly considering both bonded and nonbonded interactions. Moreover, it was shown that the contribution to stress of nonbonded interactions is more significant than that of bonded interactions.…”

Section: Introductionmentioning

confidence: 99%

“…Interestingly, it was observed that the intrinsic stress tensor is insensitive to the deformation of the melt and is therefore a system parameter for given thermodynamic conditions. Furthermore, the stress−optical coefficient representing the ratio of birefringence to global stress, can be expressed in terms of intrinsic stresses. , These remarkable properties point to the investigation of the structural origins of the intrinsic stress. The results of this investigation are discussed next.…”

Section: Introductionmentioning

confidence: 99%

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Intrinsic Distribution and Atomic Level Stress in Polymeric Melts

Picu

1999

Macromolecules

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The relationship between stress production and relaxation on one hand and the local structure on the other is studied in model polymeric melts by the use of equilibrium and nonequilibrium molecular dynamics. The analysis is performed in the intrinsic coordinate systema mobile frame tied to the generic bond. The variation of the intrinsic distribution of interacting neighbors about a representative atom, g̃, with density and temperature is investigated above and below the glass transition. It is shown that g̃ captures close packing effects and the buildup of structure upon transition, similar to the radial distribution function g(r). When computed from the nearest nonbonded neighbors, the intrinsic distribution is nonuniform due to steric shielding. Neighbors at distances larger than a covalent bond length from the representative atom, however, lead to a uniform distribution g̃. Thus, the steric shielding effect generates a nonzero intrinsic deviatoric stress in both equilibrium and nonequilibrium systems, while longer range interactions do not contribute to deviatoric stress production. Consequently, each intrinsic frame carries a nonhydrostatic stress (induced by both bonded and nonbonded interactions) which, upon rotation in the global coordinate system, contributes to the global stress in the melt. A preferential orientation of intrinsic frames (induced, for instance, by the deformation of the fluid) generates therefore a deviatoric global stress. In nonequilibrium simulations, the intrinsic distribution is seen to be independent of the deformation of the fluid. Furthermore, when computed from chain inner atoms, the intrinsic distribution is also chain length independent. This implies, in turn, that intrinsic stresses are deformation and chain length independent. The relevance of these observations to stress relaxation in polymeric melts is discussed.

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Toward a unified view of stress in small-molecular and in macromolecular liquids

Cited by 20 publications

References 22 publications

Testing Rigidity Transitions in Glass and Crystal Forming Dense Liquids: Viscoelasticity and Dynamical Gaps

Testing Rigidity Transitions in Glass and Crystal Forming Dense Liquids: Viscoelasticity and Dynamical Gaps

Estimation of Macromolecular Configurational Properties from Atomistic Simulations of Oligomers under Nonequilibrium Conditions

Intrinsic Distribution and Atomic Level Stress in Polymeric Melts

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