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543 results on '"Marrucci, Giuseppe"'

1. Persistence length and plateau modulus of semiflexible entangled polymers in primitive chain network simulations

Author

Masubuchi, Yuichi, Tassieri, Manlio, Ianniruberto, Giovanni, and Marrucci, Giuseppe

Subjects
Condensed Matter - Soft Condensed Matter
Abstract

The relationship between the plateau modulus (G_0) and the persistence length (L_p) of entangled semiflexible polymers is still uncertain. Some previous theoretical models have predicted that G_0 decreases with increasing L_p, while experiments indicated the opposite. In this study, we extend the primitive chain network (PCN) model to incorporate bending rigidity at the scale of the entanglement length, consistently with the coarse graining of the model. Simulations investigate the effects of rigidity (and of molecular weight) on chain conformation and relaxation modulus. Our results reveal a relationship described as G_0~L_p^(2/3), indicating that G_0 increases with increasing L_p, consistently with experiments. It should be considered, however, that implicit in our simulations is the condition that the entanglement length is kept fixed with changing L_p., Comment: 14 pages, 6 figures

Published
2024

2. Primitive Chain Network Simulations of Entangled Melts of Symmetric and Asymmetric Star Polymers in Uniaxial Elongational Flows

Author

Masubuchi, Yuichi, Ianniruberto, Giovanni, and Marrucci, Giuseppe

Subjects
Condensed Matter - Soft Condensed Matter, Physics - Chemical Physics
Abstract

Ianniruberto and Marrucci developed a theory whereby entangled branched polymers behave like linear ones in fast elongational flows. In order to test such prediction, Huang et al. performed elongational measurements on star polymer melts, indeed revealing that, in fast flows, the elongational viscosity is insensitive to the molecular structure, provided the molecular weight of the backbone is the same. Inspired by these studies, we here report on results obtained with multi-chain slip-link simulations for symmetric and asymmetric star polymer melts, as well as calculations of the Rouse time of the examined branched structures. The simulations semi-quantitatively reproduce the experimental data if the Kuhn-segment orientation-induced reduction of friction (SORF) is accounted for. The observed insensitivity of the nonlinear elongational viscosity to the molecular structure for the same span molar mass may be due to several factors. In the symmetric case, the calculated Rouse time of the star marginally differs from that of the linear molecule, so that possible differences in the observed stress fall within the experimental uncertainty. Secondly, it is possible that the flow-induced formation of hooked star pairs makes the effective Rouse time of the aggregate even closer to that of the linear polymer because the friction center moves towards the branchpoint of the star molecule. In the asymmetric case, it is shown that the stress contributed by the short arms is negligible with respect to that of the long ones. However, such stress-reduction is balanced by a dilution effect whereby the unstretched arms reduce SORF as they decrease the Kuhn-segment order parameter of the system. As a result of that dilution, the stress contributed by the backbone is larger. The two effects compensate one another so that the overall stress is virtually the same as the other architectures., Comment: 19 pages, 6 figures

Published
2021
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3. Wall slip in primitive chain network simulations of shear startup of entangled polymers and its effect on the shear stress undershoot

Author

Masubuchi, Yuichi, Vlassopoulos, Dimitris, Ianniruberto, Giovanni, and Marrucci, Giuseppe

Subjects
Condensed Matter - Soft Condensed Matter, Physics - Chemical Physics
Abstract

In some recent experiments on entangled polymers of stress growth in startup of fast shear flows an undershoot in the shear stress is observed following the overshoot, i.e., before approaching the steady state. Whereas tumbling of the entangled chain was proposed to be at its origin, here we investigate another possible cause for the stress undershoot, i.e., slippage at the interface between polymer and solid wall. To this end, we extend the primitive chain network model to include slip at the interface between entangled polymeric liquids and solid walls with grafted polymers. We determine the slip velocity at the wall, and the shear rate in the bulk, by imposing that the shear stress in the bulk polymers is equal to that resulting from the polymers grafted at the wall. After confirming that the predicted results for the steady state are reasonable, we examine the transient behavior. The simulations confirm that slippage weakens the magnitude of the stress overshoot, as reported earlier. The undershoot is also weakened, or even disappears, because of a reduced coherence in molecular tumbling. In other words, the disentanglement between grafted and bulk chains, occurring throughout the stress overshoot region, does not contribute to the stress undershoot., Comment: 38 pages and 9 figures

Published
2020
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11. Wall slip in primitive chain network simulations of shear startup of entangled polymers and its effect on the shear stress undershoot

Author

Masubuchi, Yuichi, Vlassopoulos, Dimitris, Ianniruberto, Giovanni, Marrucci, Giuseppe, Masubuchi, Yuichi, Vlassopoulos, Dimitris, Ianniruberto, Giovanni, and Marrucci, Giuseppe

Abstract

In some recent experiments on entangled polymers of stress growth in the startup of fast shear flows, an undershoot in the shear stress is observed following the overshoot, i.e., before approaching the steady state. Whereas tumbling of the entangled chain was proposed to be at its origin, here, we investigate another possible cause for the stress undershoot, i.e., slippage at the interface between the polymer and solid wall. To this end, we extend the primitive chain network model to include slip at the interface between entangled polymeric liquids and solid walls with grafted polymers. We determine the slip velocity at the wall, and the shear rate in the bulk, by imposing that the shear stress in the bulk polymers is equal to that resulting from the polymers grafted at the wall. After confirming that the predicted results for the steady state are reasonable, we examine the transient behavior. The simulations confirm that slippage weakens the magnitude of the stress overshoot, as reported earlier. The undershoot is also weakened, or even disappears, because of a reduced coherence in molecular tumbling. Disentanglement of grafted chains from bulk ones, taking place throughout the stress overshoot region, does not contribute to the stress undershoot.

Published
2022

26. Late Papers

Author

Astarita, Giovanni, Marrucci, Giuseppe, Nicolais, Luigi, Astarita, Giovanni, editor, Marrucci, Giuseppe, editor, and Nicolais, Luigi, editor

Published
1980
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28. Structure of entangled polymer network from primitive chain network simulations.

Author

Masubuchi, Yuichi, Uneyama, Takashi, Watanabe, Hiroshi, Ianniruberto, Giovanni, Greco, Francesco, and Marrucci, Giuseppe

Subjects
POLYMERS, EQUILIBRIUM, SIMULATION methods & models, RHEOLOGY, MACROMOLECULES
Abstract

The primitive chain network (PCN) model successfully employed to simulate the rheology of entangled polymers is here tested versus less coarse-grained (lattice or atomistic) models for what concerns the structure of the network at equilibrium (i.e., in the absence of flow). By network structure, we mean the distributions of some relevant quantities such as subchain length in space or in monomer number. Indeed, lattice and atomistic simulations are obviously more accurate, but are also more difficult to use in nonequilibrium flow situations, especially for long entangled polymers. Conversely, the coarse-grained PCN model that deals more easily with rheology lacks, strictly speaking, a rigorous foundation. It is therefore important to verify whether or not the equilibrium structure of the network predicted by the PCN model is consistent with the results recently obtained by using lattice and atomistic simulations. In this work, we focus on single chain properties of the entangled network. Considering the significant differences in modeling the polymer molecules, the results here obtained appear encouraging, thus providing a more solid foundation to Brownian simulations based on the PCN model. Comparison with the existing theories also proves favorable. [ABSTRACT FROM AUTHOR]

Published
2010
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29. Primitive chain network simulations for entangled DNA solutions.

Author

Masubuchi, Yuichi, Furuichi, Kenji, Horio, Kazushi, Uneyama, Takashi, Watanabe, Hiroshi, Ianniruberto, Giovanni, Greco, Francesco, and Marrucci, Giuseppe

Subjects
DNA polymerases, CONFORMATIONAL analysis, DEFORMATIONS (Mechanics), MOLECULAR theory, RHEOLOGY, POLYMERS
Abstract

Molecular theories for polymer rheology are based on conformational dynamics of the polymeric chain. Hence, measurements directly related to molecular conformations appear more appealing than indirect ones obtained from rheology. In this study, primitive chain network simulations are compared to experimental data of entangled DNA solutions [Teixeira et al., Macromolecules 40, 2461 (2007)]. In addition to rheological comparisons of both linear and nonlinear viscoelasticities, a molecular extension measure obtained by Teixeira et al. through fluorescent microscopy is compared to simulations, in terms of both averages and distributions. The influence of flow on conformational distributions has never been simulated for the case of entangled polymers, and how DNA molecular individualism extends to the entangled regime is not known. The linear viscoelastic response and the viscosity growth curve in the nonlinear regime are found in good agreement with data for various DNA concentrations. Conversely, the molecular extension measure shows significant departures, even under equilibrium conditions. The reason for such discrepancies remains unknown. [ABSTRACT FROM AUTHOR]

Published
2009
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30. Statics, linear, and nonlinear dynamics of entangled polystyrene melts simulated through the primitive chain network model.

Author

Yaoita, Takatoshi, Isaki, Takeharu, Masubuchi, Yuichi, Watanabe, Hiroshi, Ianniruberto, Giovanni, Greco, Francesco, and Marrucci, Giuseppe

Subjects
POLYMERS, POLYSTYRENE, RHEOLOGY, DIFFUSION, EQUILIBRIUM
Abstract

Simulation results of the primitive chain network (PCN) model for entangled polymers are compared here to existing data of diffusion coefficient, linear and nonlinear shear and elongational rheology of monodisperse polystyrene melts. Since the plateau modulus of polystyrene is well known from the literature, the quantitative comparison between the whole set of data and simulations only requires a single adjustable parameter, namely, a basic time. The latter, however, must be consistent with the known rheology of unentangled polystyrene melts, i.e., with Rouse behavior, and is therefore not really an adjustable parameter. The PCN model adopted here is a refined version of the original model, incorporating among other things a more accurate description of chain end dynamics as well as finite extensibility effects. In the new version, we find good agreement with linear rheology, virtually without adjustable parameters. It is also shown that, at equilibrium, Gaussian statistics are well obeyed in the simulated network. In the nonlinear range, excellent agreement with data is found in shear, whereas discrepancies and possible inadequacies of the model emerge in fast uniaxial elongational flows, even when accounting for finite extensibility of the network strands. [ABSTRACT FROM AUTHOR]

Published
2008
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31. Highly entangled polymer primitive chain network simulations based on dynamic tube dilation.

Author

Yaoita, Takatoshi, Isaki, Takeharu, Masubuchi, Yuichi, Watanabe, Hiroshi, Ianniruberto, Giovanni, Greco, Francesco, and Marrucci, Giuseppe

Subjects
VISCOELASTICITY, CONTINUUM mechanics, MACROMOLECULES, NUCLEAR reactions, SCATTERING (Physics), PHYSICAL sciences
Abstract

The concept of dynamic tube dilation (DTD) is here used to formulate a new simulation scheme to obtain the linear viscoelastic response of long chains with a large number of entanglements. The new scheme is based on the primitive chain network model previously proposed by some of the authors, and successfully employed to simulate linear and nonlinear behavior of moderately entangled polymers. Scaling laws are generated by the DTD concept, and allow for prediction of the linear response of very long chains on the basis of suitable simulations performed on shorter ones, without introducing adjustable parameters. Tests of the method against existing data for linear monodisperse polyisoprene and polystyrene show good quantitative agreement.© 2004 American Institute of Physics. [ABSTRACT FROM AUTHOR]

Published
2004
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32. Brownian simulations of a network of reptating primitive chains.

Author

Masubuchi, Yuichi, Takimoto, Jun-Ichi, Koyama, Kiyohito, Ianniruberto, Giovanni, Marrucci, Giuseppe, and Greco, Francesco

Subjects
WIENER processes, LANGEVIN equations
Abstract

A new model for Brownian dynamics simulations of entangled polymeric liquids is proposed here. Chains are coarse grained at the level of segments between consecutive entanglements; hence, the system is in fact a network of primitive chains. The model incorporates not only the “individual” mechanisms of reptation and tube length fluctuation, but also collective contributions arising from the 3D network structure of the entangled system, such as constraint release. Chain coupling is achieved by fulfilling force balance on the entanglement nodes. The Langevin equation for the nodes contains both the tension in the chain segments emanating from the node and an osmotic force arising from density fluctuations. Entanglements are modeled as slip links, each connecting two chain strands. The motion of monomers through slip links, which ultimately generates reptation as well as tube length fluctuations, is also described by a suitable Langevin equation. Creation and release of entanglements is controlled by the number of monomers at the chain ends. In a creation event, the partner chain segment is chosen randomly among those spatially close to the advancing chain end. To validate the model, equilibrium dynamics simulations were run for monodisperse linear chains containing up to Z=40 entanglements. The results show, in agreement with experiments, (i) a Z[sup 3.5±0.1] dependence of the longest relaxation time, (ii) a Z[sup -2.4±0.2] dependence of the self-diffusion coefficient, and (iii) a relaxation modulus proportional to the square of the end-to-end vector correlation function, consistently with the dynamic tube dilation concept. © 2001 American Institute of Physics. [ABSTRACT FROM AUTHOR]

Published
2001
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46. METHOD FOR ANALYZING MOLECULAR MOTION OF BRANCHED LONG CHAIN POLYMER

Author

Masubuchi Y., GRECO, FRANCESCO, IANNIRUBERTO, GIOVANNI, MARRUCCI, GIUSEPPE, Masubuchi, Y., Greco, Francesco, Ianniruberto, Giovanni, and Marrucci, Giuseppe

Abstract

A method for analyzing molecular motion of a branched long chain polymer wherein the position coordinate, the orientation vector, the number of monomers in the constituent elements of a tube and counterpart tube constituent elements forming entanglement are time-developed over a unit time defined by expression 7 according to the Langevin equation defined by expression 1 on the basis of the reptation theory with regard to an inter-tube constituent element constituting each polymer produced by coarse-graining the polymers of a mixture of the branched long chain polymer material to be analyzed according to the entanglement molecular weight (step 201), the number of monomers in the constituent element of the tube is time-development according to expression 5 (step 202), the number n of monomers in the constituent element of the tube at each end of a polymer is monitored, the constituent element of the counterpart tube forming entanglement is altered according to expression 8, and geometrical position exchange is caused to take place between the entanglement and a branch point by the number of constituent element of the tube at a branch part belonging to the branch point

Published
2004

50. METHOD FOR ANALYZING MOLECULAR MOTION OF COPOLYMER

Author

Masubuchi Y, GRECO, FRANCESCO, IANNIRUBERTO, GIOVANNI, MARRUCCI, GIUSEPPE, Masubuchi, Y, Greco, Francesco, Ianniruberto, Giovanni, and Marrucci, Giuseppe

Abstract

A method for analyzing molecular motion of a copolymer comprising a step for time-developing the constitutional element of an associated tube forming positional coordinates, an orientation vector, number of monomers in the constitutional elements of a tube and an entanglement over a unit time defined by expression 7 according to Langevin equation defined by expression 1 with regard to an inter-tube constitutional element constituting each polymer produced by coarse-graining the polymer of a mixture of a copolymer material to be analyzed based on the inter-entanglement molecular weight based on reptation theory (step 201), and a step for time-developing the number of monomers in the constitutional element of tube according to expression 5 (step 202) wherein the number n of monomers in the constitutional element of tube at each end of a polymer is monitored, the constitutional element of an associated tube forming an entanglement is altered according to expression 8, and geometrical positional exchange is caused to take place between the entanglement and a branch point by the number of constitutional elements of a tube at a branch part belonging to the branch point.

Published
2004

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