Numerical simulation of star polymers under shear flow using a coupling method of multi-particle collision dynamics and molecular dynamics

Yamamoto, Takehiro; Masaoka, Norichika

doi:10.1007/s00397-014-0817-8

Cited by 13 publications

(22 citation statements)

References 39 publications

(58 reference statements)

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“…The prefactor in eqn (15) for rings in solution results to be c y C 2.6 while for starts in solution we get c y C 3.1. The scaling relations for linear chains in shear flow are also in agreement with eqn (14) and its large-shear rate limit. Simulations 17 and experiments 18 reported m g = Wi a and tumbling frequency f tb B Wi a , typically with a C 2/3, although these exponents might change in semiflexible chains.…”

Section: Tumbling Frequency In Ring and Linear Polymerssupporting

confidence: 79%

“…The frequency ratio o L /O can be a useful quantity for determining different dynamic regimes of the sheared molecules. We find that O (in eqn (14)) and o L (or more precisely o G in eqn (10)) are directly connected with the polymer shape.…”

Section: Dynamic Regimesmentioning

confidence: 82%

“…where c f should be an O(1) constant. Before falsifying eqn (14) against simulation results, it is interesting to consider the force-balance in the molecular frame coordinates, given by the eigenvectors of the gyration tensor. In this frame, the molecular elongations can be taken as the square root of the eigenvalues of G, and we note them as X a 0 = G a 1/2 .…”

Section: A Scaling Relation For the Breathing Frequencymentioning

confidence: 99%

“…More recently, Xu and Chen 7 have presented a numerical study of star polymers with a range of functionality f A [3,60] and m = 20 in melts under shear, and Yamamoto et al have revisited the problem of sheared star polymers in solution. 14 At large enough shear rates, any measure of the polymer extension in the flow plane reveals the onset of alternating extensions and contractions of the molecule, typically analyzed from the cross correlation of the molecular elongations in the flow and gradient directions C XY (t). 15,16 This behavior is quite general and it has also been studied in linear chains (either free 17,18 or tethered 16 ) and in polymer rings under shear.…”

Section: Introductionmentioning

confidence: 99%

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Deciphering the dynamics of star molecules in shear flow

2017

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This work analyses the rotation of star polymers under shear flow, in melts, and in good solvent dilute solution. The latter is modeled by single molecule Brownian hydrodynamics, while melts are modeled using non-equilibrium molecular dynamics in closed (periodic) boxes and in open boundaries. A Dissipative Particle Dynamics (DPD) thermostat introduces pairwise monomer friction in melts at will, in directions normal and tangent to the monomer-monomer vectors. Although tangential friction is seldom modeled, we show that it is essential to control hydrodynamic effects in melts. We analyze the different sources of molecular angular momentum in solution and melts and distinguish three dynamic regimes as the shear rate [small gamma, Greek, dot above] is increased. These dynamic regimes are related with the disruption of the different relaxation mechanisms of the star in equilibrium. Although strong differences are found between harmonic springs and finitely extensible bonds, above a critical shear rate the star molecule has a "breathing" mode with successive elongations and contractions in the flow direction with frequency Ω. The force balance in the flow direction unveils a relation between Ω and the orientation angle. Using literature results for the tumbling of rings and linear chains, either in melt or in solution, we show that the relation is general. A different "tank-treading" dynamics determines the rotation of monomers around the center of mass of the molecule. We show that the tank-treading frequency does not saturate but keeps increasing with [small gamma, Greek, dot above]. This is at odds with previous studies which erroneously calculated the molecular angular frequency, used as a proxy for tank-treading.

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Section: Tumbling Frequency In Ring and Linear Polymerssupporting

confidence: 79%

Section: Dynamic Regimesmentioning

confidence: 82%

Section: A Scaling Relation For the Breathing Frequencymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Deciphering the dynamics of star molecules in shear flow

2017

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“…To date there has been a considerable amount of work on the response of flexible polymers with different architectures (e.g., linear, ring, hyperbranched and star polymers) to shear stress, which has revealed generic and specific properties of such systems. On top of experimental techniques, the development of simulation methods allowing to efficiently couple the solvent particles and monomers, a wide spectrum of behaviors has been found regarding the average deformation and the orientation as a function of the shear rate, as well as, multiple dynamic responses [3][4][5][6][7][8]. The latter encompass stretching and recoil, tumbling, tank-treading, rupture, and collapse of polymers and ultimately determine the (complex) viscoelastic response of dilute bulk phases.…”

Section: Introductionmentioning

confidence: 99%

Rotation Dynamics of Star Block Copolymers under Shear Flow

Jaramillo-Cano

Likos

Camargo

2018

Preprint

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Star block-copolymers (SBCs) are macromolecules formed by a number of diblock copolymers anchored to a common central core, being the internal monomers solvophilic and the end monomers solvophobic. Recent studies have demonstrated that SBCs constitute a self-assembling building blocks with specific softness, functionalization, shape, and flexibility. Depending on different physical and chemical parameters the SBCs can behave as flexible patchy particles. In this paper, we study the rotational dynamics of isolated SBCs using a hybrid mesoscale simulation technique. We compare three different approaches to analyse the dynamics: the laboratory frame, the non-inertial Eckart's frame, and a geometrical approximation relating the conformation of the SBC to the velocity profile of the solvent. We find that the geometrical approach is adequate when dealing with very soft systems while in the opposite extreme, the dynamics is best explained using the laboratory frame. On the other hand, the Eckart frame is found to be very general and to reproduced well both extreme cases. We also compare the rotational frequency and the kinetic energy with the definitions of the angular momentum and inertia tensor different from recent publications.

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Nanoparticle transport phenomena in confined flows

Radhakrishnan

Farokhirad

Eckmann

et al. 2019

Advances in Heat Transfer

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Nanoparticles submerged in confined flow fields occur in several technological applications involving heat and mass transfer in nanoscale systems. Describing the transport with nanoparticles in confined flows poses additional challenges due to the coupling between the thermal effects and fluid forces. Here, we focus on the relevant literature related to Brownian motion, hydrodynamic interactions and transport associated with nanoparticles in confined flows. We review the literature on the several techniques that are based on the principles of non-equilibrium statistical mechanics and computational fluid dynamics in order to simultaneously preserve the fluctuation-dissipation relationship and the prevailing hydrodynamic correlations. Through a review of select examples, we discuss the treatments of the temporal dynamics from the colloidal scales to the molecular scales pertaining to nanoscale fluid dynamics and heat transfer. As evident from this review, there, indeed has been little progress made in regard to the accurate modeling of heat transport in nanofluids flowing in confined geometries such as tubes. Therefore the associated mechanisms with such processes remain unexplained. This review has revealed that the information available in open literature on the transport properties of nanofluids is often contradictory and confusing. It has been very difficult to draw definitive conclusions. The quality of work reported on this topic is non-uniform. A significant portion of this review pertains to the treatment of the fluid dynamic aspects of the nanoparticle transport problem. By simultaneously treating the energy transport in ways discussed in this review as related to momentum transport, the ultimate goal of understanding nanoscale heat transport in confined flows may be achieved.

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Numerical simulation of star polymers under shear flow using a coupling method of multi-particle collision dynamics and molecular dynamics

Cited by 13 publications

References 39 publications

Deciphering the dynamics of star molecules in shear flow

Deciphering the dynamics of star molecules in shear flow

Rotation Dynamics of Star Block Copolymers under Shear Flow

Nanoparticle transport phenomena in confined flows

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