Your search keyword '"Giuseppe Marrucci"' showing total 129 results

1. On the startup behavior of wormlike micellar networks: The effect of different salts bound to the same surfactant molecule

Author

Rossana Pasquino, Pietro Renato Avallone, Salvatore Costanzo, Ionita Inbal, Dganit Danino, Vincenzo Ianniello, Giovanni Ianniruberto, Giuseppe Marrucci, Nino Grizzuti, Pasquino, R., Renato Avallone, P., Costanzo, S., Inbal, I., Danino, D., Ianniello, V., Ianniruberto, G., Marrucci, G., and Grizzuti, N.

Subjects

Mechanics of Materials, Mechanical Engineering, General Materials Science, Condensed Matter Physics

Abstract

We report on shear startup data for two wormlike micellar solutions, differing only in concentration and type of two binding aromatic sodium salts. The surfactant molecule is cetylpiridinium chloride at a fixed concentration (100 mM). Sodium salicylate (NaSal) and diclofenac sodium (Diclo) are used as binding salts at concentrations 68 mM NaSal and 52 mM Diclo such that both systems are fully entangled and their linear viscoelastic response is essentially identical. Both systems show the linear response typical of a wormlike micellar solution, with terminal behavior at low frequencies, a well-defined moduli crossover, and a plateau modulus. In the nonlinear regime, however, the behavior of the two systems is totally different, suggesting that the molecular structure difference of the salts and their binding activity to the surfactant molecule are both crucial to determine the fast flow behavior. The NaSal solution shows a very complex rheological response, with strain hardening and very sharp stress peaks, whereas the solution containing Diclo behaves much like ordinary linear polymers, exhibiting pronounced overshoots as well as moderate undershoots in the transient shear viscosity, before approaching the steady state. This polymerlike behavior has also been proved by successfully comparing data with predictions of a constitutive equation recently adopted for both entangled polymers and linear wormlike micelles. As far as NaSal is concerned, a phenomenological model based on rubber network theory is developed, which describes the flow singularities. A physical interpretation of the different behavior in the nonlinear regime is also suggested.

Published

2023

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

Author

Giovanni Ianniruberto, Giuseppe Marrucci, Yuichi Masubuchi, Masubuchi, Y., Ianniruberto, G., and Marrucci, G.

Subjects

Chemical Physics (physics.chem-ph), Nonlinear rheology, Molar mass, Materials science, Polymer dynamic, Mechanical Engineering, FOS: Physical sciences, Viscoelasticity, Linear molecular geometry, Mechanics, Condensed Matter - Soft Condensed Matter, Star (graph theory), Condensed Matter Physics, Stress (mechanics), Nonlinear system, Viscosity, Experimental uncertainty analysis, Molecular simulation, Mechanics of Materials, Physics - Chemical Physics, Soft Condensed Matter (cond-mat.soft), Branched polymer, General Materials Science

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., 19 pages, 6 figures

Published

2021

3. Primitive chain network simulations of the nonlinear rheology of polystyrene melts: Friction reduction and fluctuation-dissipation theorem

Author

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

Subjects

Applied Mathematics, Mechanical Engineering, General Chemical Engineering, General Materials Science, Condensed Matter Physics

Published

2023

4. Undershoots in shear startup of entangled linear polymer blends

Author

Daniele Parisi, Emmanouil Vereroudakis, Yuichi Masubuchi, Giovanni Ianniruberto, Giuseppe Marrucci, and Dimitris Vlassopoulos

Subjects

Applied Mathematics, Mechanical Engineering, General Chemical Engineering, General Materials Science, Condensed Matter Physics

Published

2023

5. Double Stress Overshoot in Start-Up of Simple Shear Flow of Entangled Comb Polymers

Author

Hyojoon Lee, Giovanni Ianniruberto, Giuseppe Marrucci, Taihyun Chang, Dimitris Vlassopoulos, Jin-Seok Yang, Frank Snijkers, F., Snijker, D., Vlassopoulo, Ianniruberto, Giovanni, G., Marrucci, H., Lee, J., Yang, and T., Chang

Subjects

chemistry.chemical_classification, 010304 chemical physics, Polymers and Plastics, business.industry, Chemistry, Organic Chemistry, Flow (psychology), 02 engineering and technology, Mechanics, Polymer, 021001 nanoscience & nanotechnology, 01 natural sciences, Inorganic Chemistry, Simple shear, Stress (mechanics), Optics, Rheology, Orientation (geometry), 0103 physical sciences, Materials Chemistry, Overshoot (microwave communication), Shear stress, 0210 nano-technology, business

Abstract

We report on the unusual response of a well-characterized entangled comb polymer in simple shear flow. The polymer with highly entangled backbone (about 16 entanglements) and on average 29 long branches (about 3 entanglements each) has been extensively characterized by interaction chromatography and its rheology carefully studied under controlled conditions using a special cone partitioned-plate geometry. We observe that the start-up shear stress becomes roughly rate independent above a certain critical rate, related to the relaxation time of the branches. Within the rate-independent region, the start-up shear stress displays a double overshoot. We interpret these observations in light of tube-based pompom dynamics. The key idea is that for sufficiently long branches the main stress overshoot, which reflects backbone stretching and orientation, is preceded by the withdrawal of branches into the backbone tube. The excellent quantitative comparison between the simulations and experiments supports the proposed mechanism of the double stress overshoot.

Published

2022

6. Molecular Dynamics Reveals a Dramatic Drop of the Friction Coefficient in Fast Flows of Polymer Melts

Author

Giuseppe Marrucci, Giovanni Ianniruberto, Ianniruberto, G., and Marrucci, G.

Subjects

Friction coefficient, chemistry.chemical_classification, Materials science, Polymers and Plastics, Drop (liquid), Organic Chemistry, Thermodynamics, 02 engineering and technology, Polymer, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Inorganic Chemistry, Molecular dynamics, chemistry, Materials Chemistry, 0210 nano-technology

Abstract

We here revisit existing results of Kremer-Grest molecular dynamics simulations of polymer melts that provide values of the friction coefficient ζ of the Kremer-Grest bead for the coarse-grained Fraenkel chain model, both at equilibrium, and in very fast uniaxial extensional flows. The Fraenkel chain model is chosen because it can guarantee chain inextensibility in the flow-induced fully aligned conformation. Since the value of ζaligned for the fully aligned conformation is found to be much smaller than the equilibrium value ζeq, a controversial issue of the nonlinear rheology of polymer melts is here resolved. Indeed, this finding confirms previous evidence emerging from the rheology of several polymers, where seemingly the friction coefficient decreases with increasing flow-induced molecular coalignment. Often, however, such evidence was indirect, and the friction coefficient reduction has not been accepted by a large fraction of the scientific community.

Published

2020

7. Primitive chain network simulations for H-polymers under fast shear

Author

Giuseppe Marrucci, Giovanni Ianniruberto, Yuichi Masubuchi, Masubuchi, Y., Ianniruberto, G., and Marrucci, G.

Subjects

chemistry.chemical_classification, Materials science, Dispersity, General Chemistry, Polymer, Mechanics, Condensed Matter Physics, Viscoelasticity, Shear (sheet metal), Physics::Fluid Dynamics, Condensed Matter::Soft Condensed Matter, Viscosity, chemistry, Chain (algebraic topology), Rheology, Brownian motion

Abstract

Branchpoint Withdrawal (BPW) has been recognized as one of the important molecular mechanisms for the description of the dynamics of entangled branched polymers under fast flows. However, the relation to the other known molecular mechanisms has not been fully elucidated yet. In this study we performed primitive chain network (i.e., multi-chain slip-link) Brownian simulations for a melt of a well-characterized monodisperse polystyrene H-polymer, for which the linear viscoelasticity and shear viscosity growth curves at several shear rates are available in the literature. After confirming the consistency of the simulations with the rheological data, we used the simulations to analyze the molecular motion in detail. The results reveal that molecular tumbling occurs in branched polymers just as in linear ones, and that it is accelerated by BPW. Furthermore, BPW not only mitigates backbone stretch, as expected, but also arm stretch. However, because the transient startup viscosity is anyhow dominated by chain stretch dynamics rather than by molecular tumbling, our results rationalize the fact that pom–pom theories successfully ignore tumbling in shear flows., ファイル公開：2021/01/28

Published

2020

8. Strain Hardening of Unentangled Polystyrene Solutions in Fast Shear Flows

Author

Salvatore Costanzo, Vincenzo Ianniello, Rossana Pasquino, Nino Grizzuti, Giovanni Ianniruberto, Giuseppe Marrucci, Costanzo, S., Ianniello, V., Pasquino, R., Grizzuti, N., Ianniruberto, G., and Marrucci, G.

Subjects

Inorganic Chemistry, Polymers and Plastics, Organic Chemistry, Materials Chemistry

Published

2022

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

Author

Giovanni Ianniruberto, Yuichi Masubuchi, Dimitris Vlassopoulos, Giuseppe Marrucci, Masubuchi, Y., Vlassopoulos, D., Ianniruberto, G., and Marrucci, G.

Subjects

Chemical Physics (physics.chem-ph), Steady state, Materials science, Mechanical Engineering, FOS: Physical sciences, Mechanics, Slip (materials science), Condensed Matter - Soft Condensed Matter, Condensed Matter Physics, Stress (mechanics), Shear (sheet metal), Shear rate, Rheology, Mechanics of Materials, Physics - Chemical Physics, Shear stress, Soft Condensed Matter (cond-mat.soft), General Materials Science, Slippage

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

2021

10. Melts of Linear Polymers in Fast Flows

Author

Giovanni Ianniruberto, Giuseppe Marrucci, Yuichi Masubuchi, Ianniruberto, G., Marrucci, G., and Masubuchi, Y.

Subjects

chemistry.chemical_classification, Work (thermodynamics), Materials science, Polymers and Plastics, Polymer science, Linear polymer, Organic Chemistry, macromolecular substances, 02 engineering and technology, Polymer, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Extensional definition, 0104 chemical sciences, Inorganic Chemistry, chemistry, Rheology, Materials Chemistry, 0210 nano-technology

Abstract

We report on recent progress in our understanding of the rheological behavior of polymer melts, resulting from the work of several investigators, mostly on fast extensional flows. They contributed new data from cleverly conceived experiments, new results of Brownian and molecular dynamics simulations, and suitable theoretical models. The outcome of such collective effort is the plausible certainty that flow-induced coalignment of the Kuhn segments of the polymer modifies the friction coefficient, which may depart considerably from the equilibrium value. It is also found that the effect is sensitive to the chemistry, being different in different polymers. It so appears that the universality of the rheological behavior of polymer melts, well documented under equilibrium conditions and in relatively slow flows, is lost in fast ones. This feature, however, opens interesting perspectives of future research and application.

Published

2020

11. Stress Undershoot of Entangled Polymers under Fast Startup Shear Flows in Primitive Chain Network Simulations

Author

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

Subjects

chemistry.chemical_classification, Materials science, 010304 chemical physics, Viscosity, Mechanical Engineering, Condensed Matter Physic, 02 engineering and technology, Polymer, Mechanics, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, Shear (sheet metal), Stress (mechanics), Molecular simulation, chemistry, Nonlinear viscoelasticity, Mechanics of Materials, 0103 physical sciences, Chain network, Mechanics of Material, General Materials Science, Materials Science (all), 0210 nano-technology

Published

2018

12. Shear banding in Doi–Edwards fluids

Author

Giuseppe Marrucci, Giovanni Ianniruberto, Ianniruberto, Giovanni, and Marrucci, Giuseppe

Subjects

Physics, 010304 chemical physics, Mechanical Engineering, Mathematical analysis, Constitutive equation, Condensed Matter Physics, 01 natural sciences, Instability, Integral equation, Simple shear, Shear modulus, Shear rate, Classical mechanics, Shear (geology), Mechanics of Materials, 0103 physical sciences, General Materials Science, 010306 general physics, Shear flow

Abstract

We here extend to integral constitutive equations of the Doi–Edwards type the analysis of shear banding instabilities during shear startup recently performed by Moorcroft and Fielding [J. Rheol. 58, 103–147 (2014)]. Shear banding is the instability encountered in simple shear flows, whereby different shear rates coexist along the sample thickness, so that the velocity profile departs from the usually assumed linear profile. Results of both linear and nonlinear stability analysis mostly confirm those obtained by Moorcroft and Fielding [J. Rheol. 58, 103–147 (2014)] with the Rolie–Poly equation [Likhtman, A. E., and R. S. Graham, J. Non-Newtonian Fluid Mechan. 114, 1–12 (2003)] (which is an approximate differential counterpart of the Doi–Edwards integral one “[The Theory of Polymer Dynamics (Clarendon, Oxford, 1986)]”), but some significant differences are also found. Features that coincide with those predicted by the Rolie–Poly equation include: (i) For the nonmonotonic flow curve of the original Doi–Edwar...

Published

2017

13. Modeling unentangled polystyrene melts in fast elongational flows

Author

Antonio Brasiello, Giovanni Ianniruberto, Giuseppe Marrucci, Ianniruberto, G., Brasiello, A., and Marrucci, G.

Subjects

Materials science, Polymers and Plastics, Flow (psychology), Thermodynamics, 02 engineering and technology, polystyrene, 010402 general chemistry, 01 natural sciences, Inorganic Chemistry, chemistry.chemical_compound, Rheology, friction coefficient, Materials Chemistry, Kuhn length, Brownian motion, Friction coefficient, Brownian simulation, Organic Chemistry, Relaxation (NMR), 021001 nanoscience & nanotechnology, 0104 chemical sciences, Nonlinear system, chemistry, Polystyrene, 0210 nano-technology

Abstract

Recent data of unentangled polystyrene melts in startup elongational flow and subsequent relaxation [Matsumiya, Y.;Watanabe, H.;Masubuchi, Y.;Huang, Q.;Hassager, O.Nonlinear Elongational Rheology of Unentangled Polystyrene and Poly(p-Tert-Butylstyrene) Melts.Macromolecules2018,51(23), 9710−9729] are here compared to the predictions of Brownian simulations of Fraenkel chains endowed with a monomeric friction coefficient that decreases with increasing the order parameter of the Kuhn segments. The model compares favorably with all startup data if a time delay in reducing the monomeric friction coefficient is accounted for in the fastest flows, a feature already observed by Matsumiya et al. The same model also describes the relaxation data except for a minor discrepancy in the longest relaxation time, probably due to the imperfect monodispersity of the sample and/or to a minor influence of topological interactions, not strong enough to be called entanglements. A discrepancy is also observed at the beginning of relaxation after fast flows, the origin of which remains unexplained.

Published

2019

14. Do Repeated Shear Startup Runs of Polymeric Liquids Reveal Structural Changes?

Author

Giovanni Ianniruberto, Giuseppe Marrucci, Ianniruberto, Giovanni, and Giuseppe, Marrucci

Subjects

Inorganic Chemistry, Waiting time, Physics, Polymers and Plastics, Shear (geology), Linear polymer, Organic Chemistry, Materials Chemistry, Monotonic function, Mechanics, Integral equation, Simulation

Abstract

Using the integral equation of the Doi–Edwards theory that only accounts for tube orientation of entangled linear polymers, we explore the behavior of the stress maximum typically observed in shear startup as a function of the waiting time tw between repeated startup runs. Depending on whether the first run is interrupted before the maximum, or sufficiently beyond it, the magnitude of the peak in the second run comes out nonmonotonic with tw or else monotonically increasing, respectively. A similar behavior has been observed in several experiments and commonly attributed to structural changes of the entangled network. By emphasizing the role played by the mere orientation of the network strands in faithfully reproducing all the observed behavior, at least qualitatively, our results help to put things in better perspective.

Published

2014

15. Shear and Extensional Rheology of Polystyrene Melts and Solutions with the Same Number of Entanglements

Author

Giuseppe Marrucci, Qian Huang, Ole Hassager, Dimitris Vlassopoulos, Salvatore Costanzo, Giovanni Ianniruberto, Costanzo, Salvatore, Huang, Qian, Ianniruberto, Giovanni, Marrucci, Giuseppe, Hassager, Ole, and Vlassopoulos, Dimitris

Subjects

Materials science, Polymers and Plastics, Thermodynamics, Mineralogy, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Viscoelasticity, Physics::Fluid Dynamics, Inorganic Chemistry, Molecular dynamics, chemistry.chemical_compound, Rheology, Materials Chemistry, chemistry.chemical_classification, Organic Chemistry, Polymer, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Condensed Matter::Soft Condensed Matter, Simple shear, Nonlinear system, chemistry, Shear (geology), Polystyrene, 0210 nano-technology

Abstract

We investigate the nonlinear shear and uniaxial extensional rheology of entangled polystyrene (PS) melts and solutions having the same number Z of entanglements, hence identical linear viscoelasticity. While experiments in extensional flows confirm that PS melts and solutions with the same Z behave differently, respective transient and steady data in simple shear over the largest possible range of rheometric shear rates (corresponding to Rouse−Weissenberg numbers from 0.01 to 40) demonstrate that melts and solutions exhibit identical behavior. Whereas the differences between melts and solutions in elongational flows are due to alignment-induced friction reduction (more effective in melts than in solutions), in shear flows they disappear since the rotational component reduces monomeric alignment substantially. Recent molecular dynamics simulations of entangled polymers show that rotation induces molecular tumbling at high shear rates, and here a tube-based model involving tumbling effects is proposed in or...

Published

2016

16. Measuring and assessing first and second normal stress differences of polymeric fluids with a modular cone-partitioned plate geometry

Author

Giovanni Ianniruberto, Dimitris Vlassopoulos, Salvatore Costanzo, Giuseppe Marrucci, Costanzo, Salvatore, Ianniruberto, Giovanni, Marrucci, Giuseppe, and Vlassopoulos, Dimitris

Subjects

Materials science, Rheometer, 02 engineering and technology, 01 natural sciences, chemistry.chemical_compound, Second normal stress difference, 0103 physical sciences, Cone-partitioned plate rheometry, General Materials Science, chemistry.chemical_classification, 010304 chemical physics, Start-up experiment, business.industry, Polymer, Mechanics, Modular design, Atmospheric temperature range, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Nonlinear system, chemistry, Shear (geology), Polystyrene, Materials Science (all), 0210 nano-technology, business, Shear flow

Abstract

We propose a simple, robust method to measure both the first and second normal stress differences of polymers, hence obtaining the full set of viscometric material functions in nonlinear shear flow. The method is based on the use of a modular cone-partitioned plate (CPP) setup with two different diameters of the inner plate, mounted on a rotational strain-controlled rheometer. The use of CPP allows extending the measured range of shear rates without edge fracture problems. The main advantage of such a protocol is that it overcomes limitations of previous approaches based on CPP (moderate temperatures not exceeding 120 °C, multiple measurements of samples with different volume) and yields data over a wide temperature range by performing a two-step measurement on two different samples with the same volume. The method was tested with two entangled polystyrene solutions at elevated temperatures, and the results were favorably compared with both the limited literature data on the second normal stress difference and the predictions obtained with a recent tube-based model of entangled polymers accounting for shear flow-induced molecular tumbling. Limitations and possible improvements of the proposed simple experimental protocol are also discussed.

Published

2018

17. New Interpretation of Shear Thickening in Telechelic Associating Polymers

Author

Giovanni Ianniruberto, Giuseppe Marrucci, Ianniruberto, Giovanni, and Marrucci, Giuseppe

Subjects

Materials Chemistry2506 Metals and Alloy, chemistry.chemical_classification, Dilatant, Polymers and Plastic, Polymers and Plastics, Polymer science, Organic Chemistry, Network structure, Polymer, Inorganic Chemistry, chemistry, Shear (geology), Polymer chemistry, Materials Chemistry, Shear flow, Nonlinear elasticity, Gradient direction

Abstract

Shear thickening of telechelic associating polymers, particularly of hydrophobically modified ethoxylated urethanes (HEURs), is classically attributed to either non-Gaussian behavior of the chains, also called finite extensible nonlinear elasticity (FENE), or to flow-enhanced formation of network strands; however, in a recent paper [Macromolecules, 45, 888 (2012)], Suzuki et al. show that neither of the previously mentioned interpretations can hold true, as they find shear thickening while at the same time the network structure has essentially remained the equilibrium one, except for the fact that reassociation to the network of the strands that continuously detach from it is anisotropically enhanced in the shear gradient direction. In the present paper, we propose a different mechanism that might explain shear thickening, namely, the stress contribution arising from the repulsive interaction between the flowerlike micelles that are forced to interpenetrate one another by the shear flow. In support of thi...

Published

2015

18. Entangled Melts of Branched PS Behave Like Linear PS in the Steady State of Fast Elongational Flows

Author

Giovanni Ianniruberto, Giuseppe Marrucci, Ianniruberto, Giovanni, and Giuseppe, Marrucci

Subjects

Quantitative Biology::Biomolecules, Materials science, Steady state, Polymers and Plastics, Linear polymer, Organic Chemistry, Thermodynamics, Quantum Physics, Condensed Matter::Soft Condensed Matter, Inorganic Chemistry, Stress (mechanics), Flow (mathematics), Polymer chemistry, Materials Chemistry

Abstract

The classical Doi–Edwards theory for the steady-state stress of entangled linear polymers in uniaxial elongational flow is here extended to entangled branched polymers, specifically to stars and po...

Published

2012

19. Non-Equilibrium Molecular Dynamics of Oligomeric Chains

Author

Giuseppe Marrucci, Gun Woo Park, Giovanni Ianniruberto, Antonio Brasiello, Ianniruberto, G., Giuseppe Andronico, Roberto Bellotti, Guglielmo de Nardo, Giuliano Laccetti, Giorgio Maggi, Leonardo Merola, Guido Russo, Lucia Silvestris, Sabina Tangaro, Enrico Tassi, Brasiello, A., Park, G., and Marrucci, G.

Subjects

Molecular dynamics, Materials science, shear flow, Chemical physics, polymer dynamics, friction factor, elongational flow, polystyrene

Published

2017

20. Entanglement molecular weight and frequency response of sliplink networks.

Author

Yuichi Masubuchi, Giovanni Lanniruberto, Francesco Greco, and Giuseppe Marrucci

Subjects

MECHANICS (Physics), MOLECULAR weights, LANGEVIN equations

Abstract

Brownian dynamics simulations of the linear viscoelastic response of entangled polymers have been performed, and compared quantitatively with some existing solution data at a fixed concentration and variable molecular weight. The model is a three-dimensional network where the nodes are sliplinks connecting chains in pair. The simulations make use of Langevin equations both for the node motion in space, and for the one-dimensional monomer sliding through sliplinks. Comparison with data is very satisfactory, but the molecular weight between entanglements that emerges from the model is unconventionally small. © 2003 American Institute of Physics. [ABSTRACT FROM AUTHOR]

Published

2003

21. Rest-time effects in repeated shear-startup runs of branched SBR polymers

Author

Giuseppe Marrucci, Fabio Bacchelli, Giovanni Ianniruberto, Salvatore Coppola, Salvatore, Coppola, Fabio, Bacchelli, Giuseppe, Marrucci, and Ianniruberto, Giovanni

Subjects

chemistry.chemical_classification, Materials science, Mechanical Engineering, Polymer, Condensed Matter Physics, Viscoelasticity, Nonlinear system, chemistry.chemical_compound, Shear (geology), Rheology, chemistry, Mechanics of Materials, General Materials Science, Polymer blend, Polystyrene, Statistical physics, Shear flow

Abstract

New data of shear startup on branched styrene-butadiene random (SBR) copolymers are reported, where the novelty consists in repeating the startup run after different rest times at zero stress. Here, the aim is one of exploring the “damage” introduced by the first run, as well as the subsequent recovery, if any, upon waiting increasingly long times. Differently from a linear sample, our branched melts show multiple peaks during the first run, as previously reported by Bacchelli [Kautschuk Gummi Kunststoffe 61, 188–191 (2008)] for similar SBR samples, and, more recently, by Snijkers et al. [ACS Macro Lett. 2, 601–604 (2013)] for a well-characterized comblike polystyrene melt. The repeated runs show an intriguing novel feature with respect to the case of linear polymers, namely, the first peak goes up initially, instead of down. The second peak goes down and seemingly recovers only after an extremely long time, longer than the largest relaxation time practically accessible to linear viscoelasticity, the latter not reaching the terminal behavior. All such features of nonlinear viscoelasticity of highly branched polymers are interpreted by using a simple theory inspired by the well-known pompom model.

Published

2014

22. Primitive Chain Network Simulations for Pom-Pom Polymers in Uniaxial Elongational Flows

Author

Giovanni Ianniruberto, Yuichi Masubuchi, Giuseppe Marrucci, Yumi Matsumiya, Hiroshi Watanabe, Yuichi, Masubuchi, Yumi, Matsumiya, Hiroshi, Watanabe, Giuseppe, Marrucci, and Ianniruberto, Giovanni

Subjects

Convection, chemistry.chemical_classification, Physics, Polymers and Plastics, Organic Chemistry, Polymer, Branching (polymer chemistry), Viscoelasticity, Inorganic Chemistry, Nonlinear system, chemistry, Thermal, Materials Chemistry, Friction reduction, Chain network, Statistical physics

Abstract

It is widely accepted that the nonlinear viscoelasticity of polymers with long chain branching can be described by the pom-pom theory [J. Rheol. 1998, 42, 81] that accounts for branchpoint withdrawal (BPW) as a nonlinear relaxation mechanism of the backbone. In spite of the remarkable success attained by refined theories derived from the original pom-pom model, there remain a few questions on the consistency with the theoretical development for linear polymers. For instance, convective constraint release (CCR) is neglected in the pom-pom theories. In this study, primitive chain network simulations were performed to investigate the details of molecular motion under uniaxial elongation. The simulation automatically includes thermal and convective constraint release via the multichain dynamics. The code that was assembled with finitely extensible nonlinear elasticity (FENE), BPW and the stretch-orientation/induced friction reduction (SORF) shows a reasonable agreement with literature data of linear viscoelas...

Published

2014

23. Convective constraint release (CCR) revisited

Author

Giuseppe Marrucci, Giovanni Ianniruberto, Ianniruberto, Giovanni, and Giuseppe, Marrucci

Subjects

Physics, Mechanical Engineering, Quantum entanglement, Condensed Matter Physics, Constraint (information theory), Molecular dynamics, Classical mechanics, Mechanics of Materials, Brownian dynamics, Stress relaxation, Relaxation (physics), General Materials Science, Shear flow, Brownian motion, Mathematical physics

Abstract

The molecular mechanism known as convective constraint release (CCR) is here revisited to account for the fact that in fast flows topological entanglements decrease in number, as recently shown by the molecular dynamics simulations of Baig et al. [Macromolecules 43, 6886–6902 (2010)] and even before by the Brownian simulations of Yaoita et al. [J. Chem. Phys. 128, 154901 (2008)]. Based on the same Brownian dynamics code, Furuichi et al. [J. Chem. Phys. 133, 174902 (2010)] suggested that the time-strain separability in step strain relaxation is influenced by the entanglement density dynamics, an idea previously explored by Archer et al. [Macromolecules 35, 10216–10224 (2002)]. The simple model that is here proposed is therefore tested against literature data of stress relaxation following large step strains, where the time-strain separability is approached in a time much longer than the expected Rouse time, a mystery that has long remained unsolved. The new CCR theory gives a simple mathematical form to the suggestion of Furuichi et al. [J. Chem. Phys. 133, 174902 (2010)] and Archer et al. [Macromolecules 43, 6886–6902 (2002)] and also, for the first time, predicts a minimum in the time-dependent damping function, in agreement with the experiments.

Published

2014

24. Primitive Chain Network Simulation of Elongational Flows of Entangled Linear Chains: Role of Finite Chain Extensibility

Author

Giovanni Ianniruberto, Takatoshi Yaoita, Takeharu Isaki, Yuichi Masubuchi, Hiroshi Watanabe, Giuseppe Marrucci, T., Yaoita, T., Isaki, Y., Masubuchi, H., Watanabe, Ianniruberto, Giovanni, and G., Marrucci

Subjects

Inorganic Chemistry, chemistry.chemical_classification, Materials science, Polymers and Plastics, Chain (algebraic topology), chemistry, Flow (mathematics), Organic Chemistry, Materials Chemistry, Chain network, Polymer, Topology, Extensibility

Abstract

For entangled linear monodisperse polymers, uniaxial elongational flow behavior was examined with the primitive chain network (PCN) simulation, which was originally formulated for a network of Gaus...

Published

2011

25. Diffusive Mixing of Polymers Investigated by Raman Microspectroscopy and Microrheology

Author

A.C. De Luca, Giulia Rusciano, Alexandr Jonáš, Antonio Sasso, Sergio Caserta, Stefano Guido, Giuseppe Pesce, Giuseppe Marrucci, A., Jona, DE LUCA, Anna Chiara, Pesce, Giuseppe, Rusciano, Giulia, Sasso, Antonio, Caserta, Sergio, Guido, Stefano, and Marrucci, Giuseppe

Subjects

Microrheology, Materials science, Polymers, Surface Properties, Diffusion, Diffusione, Analytical chemistry, Thermodynamics, Polyenes, Spectrum Analysis, Raman, Gocce, Viscosity, Rheology, Phenomenological model, Electrochemistry, General Materials Science, Dimethylpolysiloxanes, Particle Size, Spectroscopy, chemistry.chemical_classification, Surfaces and Interfaces, Polymer, Condensed Matter Physics, Condensed Matter::Soft Condensed Matter, Diffusion process, chemistry, Polymer blend, Microscopia Raman, Miscelazione

Abstract

Diffusive mixing in a model polymer blend of limited miscibility (i.e., the pair polydimethylsiloxane/polyisobutene) is investigated. The diffusion process is followed in the actual droplet-based microstructure of the polymer blend, as opposed to the ideal planar geometry used in previous studies (Brochard et al. Macromolecules 1983, 16, 1638; Composto et al. Nature 1987, 328, 234). In our experiments we combine Raman microspectroscopy and video particle-tracking microrheology. The first technique allows us to monitor local concentration of the two polymers with high spatial resolution both inside and outside a micrometer-size droplet of the dispersed phase. In addition, microrheology enables to follow how the local viscosity inside the droplet changes during the diffusion. The polymer viscosity inside the droplet is determined by video tracking the Brownian motion of a polystyrene bead microinjected into the droplet. The microspectroscopic and microrheological data are combined to estimate the concentration dependence of the monomer friction factor of the two species, which is a key parameter to calculate the interdiffusion coefficient D. Numerical calculations based on such concentration-dependent interdiffusion coefficient D and several alternative models of the polymer diffusion are compared to the experimental concentration profiles. A satisfactory agreement is found for the so-called "slow theory" (Brochard et al.). A phenomenological model improving the agreement of the model with the experimental data is also presented.

Published

2010

26. Primitive Chain Network Simulations of Conformational Relaxation for Individual Molecules in the Entangled State. II. Retraction from Stretched States

Author

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

Subjects

Entangled polymers, Work (thermodynamics), Individual polymer motion, Materials science, Thermodynamic equilibrium, Step shear deformation, Mechanical Engineering, Relaxation (NMR), State (functional analysis), Condensed Matter Physics, Molecular physics, Conformational relaxation, Shear (sheet metal), Stress (mechanics), Classical mechanics, Chain (algebraic topology), Mechanics of Materials, General Materials Science, Deformation (engineering), Primitive chain network simulation

Abstract

Although some experiments have addressed individual chain dynamics in the entangled state, the behavior of the quantity measured in the experiments, and its relation to chain conformation, deserves further study. In our previous work using primitive chain network simulations at equilibrium (Masubuchi et al, Nihon Reoroji Gakkaisi (J. Soc. Rheol. Jpn.) 36, 181, 2008), we examined the relaxation of the chain extension, x, which is the maximum distance between segments of any given chain. In this supplementary study we performed simulations under step shear deformations, away from the equilibrium state. It was found that the x relaxation under deformation is qualitatively similar to that of the relaxation modulus, where slow relaxation modes are insensitive to deformation while the intensity of fast modes is enhanced. As a result the longest relaxation time of x was found to be the same as the equilibrium state, and different from that of stress. For what concerns the behavior of the fast modes, less damping was observed for the relaxation of x than that for stress.

Published

2009

27. Quantitative comparison of primitive chain network simulations with literature data of linear viscoelasticity for polymer melts

Author

Yuichi Masubuchi, Francesco Greco, Giovanni Ianniruberto, Giuseppe Marrucci, Y., Masubuchi, Ianniruberto, Giovanni, Greco, Francesco, and Marrucci, Giuseppe

Subjects

chemistry.chemical_classification, Physics, Molar mass, Applied Mathematics, Mechanical Engineering, General Chemical Engineering, Constitutive equation, Quantum entanglement, Polymer, Condensed Matter Physics, Space (mathematics), Plateau (mathematics), Viscoelasticity, chemistry, General Materials Science, Statistical physics, Brownian motion

Abstract

The primitive chain network model of entangled polymers, where primitive chains and entanglements are assigned in real 3-D space, is a possible step in the multi-scale path from atomistic simulations to macroscopic constitutive equations. In any coarse-grained model of a polymeric system, however, determination of the basic parameters is a crucial step. By fitting the linear viscoelastic response of several melts of monodisperse linear polymers taken from the literature, we here determine the corresponding basic parameters of the primitive chain network model. We concentrate in particular on the value of the mean molar mass between entanglements, and on how such a mass is related to plateau modulus from our simulations. We consistently find values that fall around 60% of the entanglement molecular weight as obtained from Ferry's definition, and we envisage that such a result is due to Brownian fluctuations of the entanglement nodes.

Published

2008

28. Entangled polymer orientation and stretch under large step shear deformations in primitive chain network simulations

Author

Chisato Nonomura, Yuichi Masubuchi, Giuseppe Marrucci, Francesco Greco, Giovanni Ianniruberto, Kenji Furuichi, Hiroshi Watanabe, Furuichi, K., C., Nonomura, Y., Masubuchi, H., Watanabe, Ianniruberto, Giovanni, Greco, Francesco, and Marrucci, Giuseppe

Subjects

chemistry.chemical_classification, chain stretch, primitive chain network, Polymer, Mechanics, Quantum entanglement, three-chain model, Condensed Matter Physics, Viscoelasticity, Condensed Matter::Soft Condensed Matter, Nonlinear system, chemistry.chemical_compound, Reptation, Orientation tensor, chemistry, Polymer chemistry, Thermal, General Materials Science, chain orientation, Polystyrene, force balance, step shear deformation

Abstract

Orientation and stretch of entangled polymers under large step shear deformations were investigated through primitive chain network simulations. In the simulations, entangled polymer dynamics is described by 3D motion of entanglements, 1D sliding of monomers along the chain, and creation/destruction of entanglements described by hooking/unhooking with surrounding chains at chain ends. In addition to the conventionally proposed relaxation mechanisms that are reptation, contour length fluctuations, and constraint release (both thermal and convective), the simulations also account for force balance among entanglement strands converging to an entanglement node, and nodes also fluctuate in space. Nonlinear step strain data for monodisperse polystyrene melts (Ferri and Greco, Macromolecules, 37:5931, 2006) were quantitatively reproduced by using the same two molecular-weight-independent parameters already adopted by Masubuchi et al. (J Non-Newt Fluid Mech, 149:87, 2008) to fit linear viscoelastic data of several monodisperse polystyrene melts. Analysis of the orientation tensor and of the chain stretch ratio indicates that the segment orientation and stretch realized in the simulation are quantitatively described by a simple three-chain model (Marrucci et al., Macromol Symp, 158:57, 2000a).

Published

2008

29. Primitive Chain Network Simulations of Conformational Relaxation for Individual Molecules in the Entangled State

Author

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

Subjects

Materials science, Mechanical Engineering, Relaxation (NMR), Dielectric, Condensed Matter Physics, Measure (mathematics), Polarization density, Chain (algebraic topology), Mechanics of Materials, Chemical physics, Quantum mechanics, Exponent, Stress relaxation, General Materials Science, Well-defined

Abstract

Conformational relaxation of individual chain molecules in the entangled state has already been investigated by direct observation in fluorescent DNA experiments. Yet, possible connections between the quantity accessible in those experiments and well defined conformational measures have not been established so far. In this study, the relaxation behavior of the individual polymer conformation in the entangled state is simulated through the primitive chain network model, and compared to well known relaxations like that of stress or electric polarization. Inspired by the experiments, we use as a measure of the individual conformation the maximum distance between segments of a given polymer chain, which is often referred to as chain extension, and indicated by the symbol x. The relaxation behavior is calculated as auto-correlation function at equilibrium, suitably ensemble averaged to eliminate the noise. It is found that such x relaxation is significantly different from both stress relaxation and end-to-end dielectric relaxation, though the power-law exponent of the longest relaxation time vs. chain length appears to be the same for both the stress and the x measure.

Published

2008

30. Stretch/orientation Induced Acceleration in Stress Relaxation in Coarse-grained Molecular Dynamics Simulations

Author

Yumi Matsumiya, Giuseppe Marrucci, Takatoshi Yaoita, Yuichi Masubuchi, Hiroshi Watanabe, Giovanni Ianniruberto, Yuichi, Masubuchi, Takatoshi, Yaoita, Yumi, Matsumiya, Hiroshi, Watanabe, Ianniruberto, Giovanni, and Giuseppe, Marrucci

Subjects

Molecular dynamics, Acceleration, Materials science, Mechanics of Materials, Mechanical Engineering, Stress relaxation, General Materials Science, Molecular simulation, Mechanics, Orientation (graph theory), Condensed Matter Physics

Published

2013

31. Primitive chain network model for block copolymers

Author

Francesco Greco, Giovanni Ianniruberto, Yuichi Masubuchi, Giuseppe Marrucci, Masubuchi, Y., Ianniruberto, Giovanni, Greco, Francesco, and Marrucci, Giuseppe

Subjects

chemistry.chemical_classification, Boundary (topology), Sequence (biology), Polymer, Condensed Matter Physics, Electronic, Optical and Magnetic Materials, Condensed Matter::Soft Condensed Matter, Modeling and simulation, Molecular dynamics, chemistry, Chain (algebraic topology), Computational chemistry, Materials Chemistry, Ceramics and Composites, Copolymer, Statistical physics, Phase diagram

Abstract

A coarse-grained molecular simulation for block copolymers in the entangled state is proposed as an extension of the primitive chain network model. Polymers are represented as a sequence of segments between consecutive entanglements, the latter being modeled as sliplinks with other chains. Each sliplink connects two chains only, i.e., entanglements are taken as ‘binary’. The resulting 3D structure is a network of primitive chains, which makes our model different from other sliplink single-chain models, where the link to other chains is ‘virtual’. The 3D nature of our simulation makes it similar to, though considerably more coarse grained than, conventional molecular dynamics simulations. Because of the 3D space assignment of the polymers, monomeric density fields can be defined, and interactions due to different chemistry of the monomers can be accounted for, similarly to density field calculations. Polymer motion is described both by the 3D motion of sliplinks, and by the 1D transport of monomers along the primitive chain, while network topological rearrangement occurs due to chain-end hooking and unhooking processes. Each kinetic equation accounts for elastic forces along the chains, field forces arising from density gradients, and thermal random forces. In this paper, the primitive chain network model was modified (i) in the procedure of network rearrangement to account for the different chemistries in the copolymer, and (ii) in some details of the kinetic equations whenever the boundary between blocks is involved. We report results for diblock copolymers where for simplicity all relevant properties of the two monomers are the same, except for the interactions. Simulations reasonably reproduce the micro-phase formation process and the phase diagram for well entangled copolymers with a low calculation cost.

Published

2006

32. A 2D model for tube orientation and tube squeezing in fast flows of polymer melts

Author

Giovanni Ianniruberto, Giuseppe Marrucci, Ianniruberto, Giovanni, and Marrucci, Giuseppe

Subjects

Physics, Applied Mathematics, Mechanical Engineering, General Chemical Engineering, Context (language use), Mechanics, Condensed Matter Physics, Shear (sheet metal), Cross section (physics), Viscosity, Flow (mathematics), General Materials Science, Tube (fluid conveyance), Statistical physics, Deformation (engineering), Shear flow

Abstract

Motivated by recent data of Hassager and coworkers [A. Bach, K. Almdal, H.K. Rasmussen, O. Hassager, Elongational viscosity of narrow molar mass distribution polystyrene, Macromolecules, 36 (2003) 5174–5179], we develop a new tube model describing the non-linear behaviour of entangled monodisperse linear polymers. Within the context of well established tube theories, the model accounts for the effect of flow on tube diameter, thus somehow picking up a long standing suggestion by Wagner and Schaeffer [M.H. Wagner, J. Schaeffer, Non-linear strain measures for general biaxial extension of polymer melts, J. Rheol., 32 (1992) 1–26] among others. Since tubes with a deformation dependent cross section are rather difficult to deal with, we here limit model development to an artificial two-dimensional situation. The simple 2D model has the advantage of illustrating the new physical assumptions more transparently, and it already proves to correctly predict most qualitative features typically shown by shear and elongational data in the non-linear range.

Published

2005

33. Simulations of fast flows of PS oligomers confirm monomeric friction reduction in fast elongational flows of monodisperse polymers

Author

IANNIRUBERTO, GIOVANNI, Antonio Brasiello, Giuseppe Marrucci, Francesco Paolo La Mantia, Ianniruberto, Giovanni, Antonio, Brasiello, and Giuseppe, Marrucci

Published

2012

34. Primitive Chain Network Simulations on Dielectric Relaxation of Linear Polymers under Shear Flow

Author

Francesco Greco, Giuseppe Marrucci, Giovanni Ianniruberto, Hiroshi Watanabe, Yuichi Masubuchi, Ianniruberto, Giovanni, Marrucci, Giuseppe, Y., Masabuchi, H., Watanabe, and Greco, Francesco

Subjects

Materials science, shear flow, Linear polymer, Mechanical Engineering, Thermodynamics, Dielectric, dielectric relaxation, hidden entanglement appearance, Condensed Matter Physics, primitive chain network simulations, Classical mechanics, linear polymers, Mechanics of Materials, Relaxation (physics), Chain network, General Materials Science, Shear flow

Published

2004

35. Rheology : Volume 1: Principles

Author

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

Subjects

Rheology--Congresses, Polymers--Congresses, Fluid dynamics--Congresses, Suspensions (Chemistry)--Congresses

Abstract

At the VIIth International Congress on Rheology, which was held in Goteborg in 1976, Proceedings were for the first time printed in advance and distributed to all participants at the time of the Congress. Although of course we Italians would be foolish to even try to emulate our Swedish friends as far as efficiency of organization is concerned, we decided at the very beginning that, as far as the Proceedings were concerned, the VIIIth International Congress on Rheology in Naples would follow the standards of time­ liness set by the Swedish Society of Rheology. This book is the result we have obtained. We wish to acknowledge the cooperation of Plenum Press in producing it within the very tight time schedule available. Every four years, the International Congress on Rheology represents the focal point where all rheologists meet, and the state of the art is brought up to date for everybody interested; the Proceedings represent the written record of these milestones of scientific progress in rheology. We have tried to make use of the traditions of having invited lectures, and of leaving to the organizing committee the freedom to choose the lecturers as they see fit, in order to collect a group of invited lectures which gives as broad as possible a landscape of the state of the art in every relevant area of rheology. The seventeen invited lectures are collected in the first volume of the proceedings.

Published

2013

36. Entanglement molecular weight and frequency response of sliplink networks

Author

Francesco Greco, Giovanni Ianniruberto, Giuseppe Marrucci, Yuichi Masubuchi, Masubuchi, Y., Ianniruberto, Giovanni, Greco, Francesco, Marrucci, G., Marrucci, Giuseppe, and Ianniruberto, G

Subjects

entanglements, Physics, chemistry.chemical_classification, Frequency response, General Physics and Astronomy, linear viscoelasticity, Quantum entanglement, Polymer, simulation, Space (mathematics), Viscoelasticity, Classical mechanics, chemistry, Brownian dynamics, Node (circuits), Statistical physics, Physical and Theoretical Chemistry, polymers, Brownian motion

Abstract

Brownian dynamics simulations of the linear viscoelastic response of entangled polymers have been performed, and compared quantitatively with some existing solution data at a fixed concentration and variable molecular weigth. The model is a three-dimensional network where the nodes are sliplinks connecting chains in pair. The simulations make use of Langevin equations both for the node motion in space, and for the one-dimensional monomer sliding through sliplinks. Comparison with data is very satisfactory, but the molecular weigth between entanglements that emerges from the model is unconventionally small.

Published

2003

37. Flow-induced orientation and stretching of entangled polymers

Author

Giovanni Ianniruberto, Giuseppe Marrucci, Marrucci, Giuseppe, and Ianniruberto, G.

Subjects

Models, Molecular, Time Factors, Polymers, Protein Conformation, General Mathematics, Constitutive equation, Normal Distribution, General Engineering, General Physics and Astronomy, Molecular orbital theory, Models, Theoretical, Orientation (vector space), Constraint (information theory), Reptation, Classical mechanics, Rheology, Flow (mathematics), Relaxation (physics), Stress, Mechanical, Mathematics

Abstract

A single-mode constitutive equation is proposed which accounts, in a very simple way, for the most important feature of the molecular theory for entangled polymers based on the 'tube' concept, i.e. that the orientation of the tubes and the stretching of the chain within them relax over different time-scales. The much faster relaxation of stretch is essentially a Rouse process, whereas orientational relaxation takes place by a combination of several factors, including reptation, tube-length fluctuations and constraint release, both thermal and convective. The model presented here accounts for all of these mechanisms, albeit in a simplified way, with the exception of fluctuations, which cannot be dealt with in a single-mode theory. Extension to a multi-mode version should, however, be easy.

Published

2003

38. Modelling rheology and free energy of entangled polymers. State of the art

Author

Giovanni Ianniruberto, Giuseppe Marrucci, Ianniruberto, Giovanni, and Marrucci, Giuseppe

Subjects

Physics, chemistry.chemical_classification, Polymers and Plastics, Differential equation, Organic Chemistry, Molecular orbital theory, Polymer, Condensed Matter Physics, Liquid state, chemistry, Rheology, Materials Chemistry, Statistical physics, State (computer science), Energy (signal processing)

Abstract

Significant progress made in recent times on the basic molecular theory of Doi and Edwards for entangled polymers is briefly reviewed. In particular we present a recent version of the theory that is entirely described by a set of differential equations, and is therefore especially useful for simulations of complex flows as encountered in polymer processing. The model also provides an expression for the excess free energy that can be of use to predict the onset of flow-induced crystallisation.

Published

2002

39. Primitive-chain Brownian simulations of entangled rubbers

Author

J. Oberdisse, F. Greco, Giuseppe Marrucci, and Giovanni Ianniruberto

Subjects

chemistry.chemical_classification, Physics, General Physics and Astronomy, Polymer, Displacement (vector), Stress (mechanics), Classical mechanics, chemistry, Chain (algebraic topology), Rubber elasticity, Additive function, Brownian dynamics, Statistical physics, Brownian motion

Abstract

We present a new multi-chain Brownian dynamics simulation of a polymeric network containing both crosslinks and slip-links (entanglements). We coarse-grain at the level of chain segments connecting consecutive nodes (cross- or slip-links). Affine displacement of nodes is not imposed; rather, their displacement as well as sliding of monomers through slip-links is governed by force balances. The stress-strain response in uniaxial extension is compared with the slip-link theories of Ball et al. (Polymer, 22 (1981) 1010) and Edwards and Vilgis (Polymer, 27 (1986) 483), and with the molecular-dynamics simulations of Grest et al. (J. Non-Cryst. Solids, 274 (2000) 139). Qualitative agreement both with the Mooney-Rivlin expression and with the stress upturn at large strains confirms the role of entanglements in explaining departure from the classical theory of phantom chain networks. However, quantitative agreement with data is satisfactory at low strains only, and the observed discrepancy at larger strains suggests possible refinements of the model. Additivity of free energy contributions of crosslinks and entanglements used in several molecular theories of rubber elasticity is confirmed by the simulation results.

Published

2002

40. A multi-mode CCR model for entangled polymers with chain stretch

Author

Giuseppe Marrucci, Giovanni Ianniruberto, Ianniruberto, Giovanni, and Marrucci, Giuseppe

Subjects

chemistry.chemical_classification, Physics, Applied Mathematics, Mechanical Engineering, General Chemical Engineering, Polymer, Multiple modes, Condensed Matter Physics, Power law, Molten state, chemistry, General Materials Science, Statistical physics, Shear flow

Abstract

The model recently proposed by the authors [J. Rheol., 45 (2001) 1305–1318] to account for convective constraint release (CCR) and chain stretch in entangled polymers is here extended to a multiple mode situation. Such an extension, indispensable for the polydisperse case, is believed to be important also for monodisperse polymers, especially in view of chain-end fluctuations. The model is compared with existing steady and transient start-up data of shear flows. It is also shown how the model can help explaining the frequently observed power-laws, especially for the case of melts.

Published

2002

41. Primitive chain network simulations of conformational relaxation for individual molecules in the entangled state

Author

Yuichi Masubuchi, Hiroshi Watanabe, GRECO, FRANCESCO, Giuseppe Marrucci, IANNIRUBERTO, GIOVANNI, Masubuchi, Y., Watanabe, H., Ianniruberto, Giovanni, Greco, Francesco, Marrucci, Giuseppe, Yuichi, Masubuchi, Hiroshi, Watanabe, and Giuseppe, Marrucci

Subjects

primitive chain network simulation, conformational relaxation, individual polymer motion, entangled polymers

Published

2008

42. A model for the nonlinear rheology of associating polymers

Author

Giuseppe Marrucci and A Vaccaro

Subjects

Dilatant, Materials science, Shear thinning, Applied Mathematics, Mechanical Engineering, General Chemical Engineering, Relaxation (iterative method), Thermodynamics, Mechanics, Condensed Matter Physics, Physics::Fluid Dynamics, Condensed Matter::Soft Condensed Matter, Shear (sheet metal), Nonlinear system, Viscosity, Rheology, General Materials Science, Shear flow

Abstract

Theories for transient networks formed by associating telechelic polymers require that the kinetics of chain detachment and reattachment processes are somehow specified. We propose here very simple choices for such kinetics, that are nevertheless based on plausible molecular mechanisms. Specific evolution equations are then formulated for the populations of both elastically-active chains and chains temporarily detached from the network. By using typical closure approximations, the rheological model is finally elaborated into a set of ordinary differential equations. For steady shear flows, these nonlinear equations predict shear thickening at moderate shear rates followed by shear thinning at higher shear rates, in agreement with observations. In the limit of slow flows, analytical expressions for the viscosity and the relaxation times are also obtained.

Published

2000

43. Simple strain measure for entangled polymers

Author

Giovanni Ianniruberto, Giuseppe Marrucci, and Francesco Greco

Subjects

chemistry.chemical_classification, Physics, Mechanical Engineering, Constitutive equation, Infinitesimal strain theory, Polymer, Force balance, Condensed Matter Physics, Affine deformation, Reptation, Classical mechanics, chemistry, Square root, Mechanics of Materials, Lattice (order), General Materials Science, Statistical physics

Abstract

In the classical theory of Doi and Edwards for entangled polymers the strain measure Q arises from the assumption of affine deformation of the tube segments. On the other hand, we have recently argued [G. Marrucci, F. Greco, and G. Ianniruberto, “Possible role of force balance on entanglements,” Macromol. Symp. (in press)] that force balance on the nodes of the entangled network generates departures from affinity. An ad hoc “lattice” model of the network was then proposed to fulfill force balance automatically, at least for single-step deformations. The corresponding strain measure is linked to the square root of the Finger tensor, and is therefore easy to use. Predictions obtained with the new strain measure are here compared with a variety of step strain data.

Published

2000

44. Squeeze flow between finite plates

Author

Giuseppe Marrucci and Morton M. Denn

Subjects

Physics, Physics::Instrumentation and Detectors, Applied Mathematics, Mechanical Engineering, General Chemical Engineering, Mathematical analysis, Fluid mechanics, Condensed Matter Physics, Compressible flow, Physics::Fluid Dynamics, Classical mechanics, Flow (mathematics), Limit of a sequence, General Materials Science, Vector field, Potential flow, Boundary value problem, Limit (mathematics)

Abstract

The general solution for squeeze flow between closely-spaced plates of arbitrary shape includes an in-plane potential flow whose components satisfy the Cauchy–Riemann conditions, and the velocity field and the pressure are both determined by the boundary conditions at the edge of the plates. In contrast, the velocity field for the infinite-plate limit only requires boundary conditions at the surfaces of the plates. The infinite-plate problem is singular, and makes sense only as a limit of a sequence of flows in finite geometries, each of which has a well-defined coordinate origin.

Published

1999

45. Stress tensor and stress-optical law in entangled polymers

Author

Giuseppe Marrucci, Giovanni Ianniruberto, Ianniruberto, Giovanni, and G., Marrucci

Subjects

Physics, chemistry.chemical_classification, Cauchy stress tensor, Applied Mathematics, Mechanical Engineering, General Chemical Engineering, Traction (engineering), Polymer, Condensed Matter Physics, chemistry, Law, Chemical solution, General Materials Science, Stress measures, Viscous stress tensor, Anisotropy

Abstract

The molecular origin of the stress in entangled polymers is reconsidered here, in order to ascertain whether or not the pressure that the confined chain exerts on its 'tube of constraints' should be accounted for. Indeed, the classical expression for the stress includes only traction along the chain. The analysis shows that the pressure terms significantly contribute to the stress provided flow or deformation creates a long-lasting local anisotropy of the chain confinement. The effects of such anisotropy is described by means of elliptical cross-sections of the constraining tubes. The new expression for the stress tensor thus obtained properly degenerates into the classical one for circular cross sections. It is also shown that the stress-optical law remains obeyed. (C) 1998 Elsevier Science B.V. All rights reserved

Published

1998

46. Brownian dynamics of concentrated polymers in two dimensions1Dedicated to the memory of Professor Gianni Astarita.1

Author

Giuseppe Marrucci, Giovanni Ianniruberto, and E. J. Hinch

Subjects

Physics, chemistry.chemical_classification, Applied Mathematics, Mechanical Engineering, General Chemical Engineering, Dynamics (mechanics), Polymer, Condensed Matter Physics, Grid, Shear (sheet metal), Chain (algebraic topology), chemistry, Obstacle, Brownian dynamics, General Materials Science, Statistical physics, Diffusion (business)

Abstract

Two-dimensional simulations of the Brownian dynamics of polymers in a grid of topological obstacles were carried out in this study. A first model made use of the exact expression for the free energy of a chain with fixed ends interacting with an obstacle and can be used to derive the elastic force acting on the subchains of a Rouse-like model. With this model we calculated the diffusion coefficient of chains of different lengths constrained by the fixed obstacles. A second model, less rigorous but more efficient computationally, was used to simulate the chain dynamics in fast flows. In such a case, the obstacles were convected according to the shear gradient. During the simulation, the configurational changes of the chain constrained by the obstacles could be monitored and the stresses which developed were calculated. These simulations reveal important effects of the conformational fluctuations at high shear rates.

Published

1998

47. Dynamics of stiff polymers with the slightly-bending-rod model1Dedicated to the memory of Professor Gianni Astarita.1

Author

Giuseppe Marrucci, Francesco Greco, and Mario Minale

Subjects

Physics, Flexibility (anatomy), Basis (linear algebra), Applied Mathematics, Mechanical Engineering, General Chemical Engineering, Dynamics (mechanics), Rotational diffusion, Bending, Mechanics, Condensed Matter Physics, Condensed Matter::Soft Condensed Matter, Adiabatic theorem, medicine.anatomical_structure, Chain (algebraic topology), medicine, General Materials Science, Mathematical structure

Abstract

The dynamics of stiff polymers in the liquid or liquid–crystalline state is usually described by the rigid rod model. To account, at least to a first approximation, for the partial flexibility of the actual chain, the slightly-bending-rod model has been recently proposed, and a simplified two-dimensional version of the model has been developed in some detail. In this paper, we consider the full three-dimensional dynamic equation which, in its general form, is too complex for predictive purposes. We then derive a reduced form of the dynamic equation on the basis of the fact that some of the configurational variables have a much faster dynamics than others. The mathematical structure of the reduced form, though still complex, is close enough to that of the rigid rod model to allow for predictive calculations.

Published

1998

48. Tailored rigid-flexible block copolymers, 2. Intrinsic viscosity behavior

Author

Marino Novi, Carmen S. Renamayor, Piero Cavalleri, Nayaku N. Chavan, Giuseppe Marrucci, Carlo Dell'Erba, and Alberto Ciferri

Subjects

Polymers and Plastics, Chemistry, Intrinsic viscosity, Organic Chemistry, Sulfuric acid, Condensed Matter Physics, Diluent, chemistry.chemical_compound, Polymer chemistry, Materials Chemistry, Copolymer, Molecule, Degradation (geology), Physical and Theoretical Chemistry, Dispersion (chemistry), Macromolecule

Abstract

The determination of single-chain properties for heterogeneous molecules such as a rigid-flexible block copolymer requires the use of solvents capable of reducing selective interactions involving the blocks and the diluent. Molecular dispersion is displayed by a two-block copolymer of benzoyl-terminated poly(p-benzamide) (poly(imino-1,4-phenyl-enecarbonyl) and anilino-terminated poly(m-phenyleneisophthalamide) in 96 wt.-% sulfuric acid. For a series of such copolymers, intrinsic viscosities were measured avoiding degradation effects due to H 2 SO 4 . The intrinsic viscosity ([η]) of the copolymers was found to decrease with increasing length of the flexible block, but [η] remained larger than the value corresponding to an equimolar blend of rigid and flexible homopolymers. These results are explained by theoretical considerations within the framework of the hydrodynamic behavior of single rodlike and single coiled macromolecules.

Published

1997

49. The tumbling or flow-aligning nature of nematics as predicted from the Slightly Bending Rod molecular model

Author

Giuseppe Marrucci, Francesco Greco, Greco, F., and Marrucci, G.

Subjects

Materials science, Molecular model, business.industry, Chemistry (all), General Chemistry, Mechanics, Condensed Matter Physics, Rod, Rigidity (electromagnetism), Optics, Liquid crystal, General Materials Science, Materials Science (all), business

Abstract

Existing calculations of the Leslie coefficients for rigid rods endowed with the Maier-Saupe potential are here extended to investigate the consequences of relaxing the constraint of a complete molecular rigidity. In particular, the recently proposed model of the Slightly Bending Rod (SBR) is used to calculate the ratio alpha3/alpha2, the sign of which controls whether the nematic is of the tumbling or flow-aligning type. The results show that SBRs are more prone to tumbling than fully rigid rods. The flow-aligning to tumbling transition, which takes place by increasing the order parameter (e.g. by decreasing the temperature) is shifted, for SBRs, to a smaller value of the order parameter.

Published

1997

50. Dynamics of entanglements: A nonlinear model consistent with the Cox-Merz rule

Author

Giuseppe Marrucci

Subjects

Physics, Applied Mathematics, Mechanical Engineering, General Chemical Engineering, Constitutive equation, Dynamics (mechanics), Condensed Matter Physics, Thermal diffusivity, Nonlinear system, Classical mechanics, Flow (mathematics), Chain (algebraic topology), Simple (abstract algebra), Relaxation (physics), General Materials Science, Statistical physics

Abstract

It is argued that the flow directly contributes a mechanism by which the topological obstacles are renewed. As a consequence, the chain diffusivity is increased (or, equivalently, the friction coefficient is decreased) in fast flows. Such a nonlinear effect is incorporated in a simple dumbbell model so as to produce a constitutive equation in closed form. An extension to the case of multiple relaxation times is also briefly considered. The predictions compare favourably with the Cox-Merz rule as well as with the behaviour of polymer melts in elongational flows.

Published

1996