Mechanical properties of thin confined polymer films close to the glass transition in the linear regime of deformation: Theory and simulations

Dequidt, Alain; Long, Didier; Sotta, Paul; Sanséau, Olivier

doi:10.1140/epje/i2012-12061-6

Cited by 48 publications

(107 citation statements)

References 90 publications

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“…This crudely leads to a film with some fraction of glassy segments that can effectively pin the polymer chains on the time scale of the measurements . This explanation is similar to the arguments from Dequidt et al where their model uses the broadening of T g on confinement to predict as much as an order of magnitude increase in the modulus between bulk T g and T g + 50 K in comparison to the bulk polymer . Recently, Priestley and coworkers elegantly demonstrated that there is a gradient in viscosity through polymer thin films when probed with non‐contact shear, which is consistent with the distribution of properties explanation of Mirigian and Schweizer.…”

Section: Flow Properties Of Rubbery Polymers Under Confinementsupporting

confidence: 76%

Mechanical and viscoelastic properties of confined amorphous polymers

Vogt

2017

J Polym Sci B Polym Phys

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Confinement of polymers to nanoscale dimensions can dramatically impact their physical properties. Substantial efforts have focused on the glass transition temperature (T g ) of polymers confined to thin films, but their mechanical properties are less studied despite their technological importance. In this review, challenges with mechanical measurements of polymer thin films are discussed along with novel metrologies that provide insight into their mechanical properties. A comparison of experimental measurements, simulations and theory provide several general conclusions about the mechanical properties under confinement. Confinement impacts the elastic modulus, rubbery compliance and viscosity of polystyrene, the archetypal polymer for confinement, but the confinement effect appears to depend on the measurement technique. This effect may be due to the details of averaging of gradients in properties that are dependent on the measurement details. Routes to minimize confinement effects are addressed. Despite progress in the measurements of mechanical properties of polymer thin films, there remain unresolved questions about the impact of confinement, which we highlight at the end of this review. 1,2 These concerns persist for polymeric nanostructures, where mechanical properties are critical to feature stability. 3 The mechanical properties of many polymers are dependent on their processing history,

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Section: Flow Properties Of Rubbery Polymers Under Confinementsupporting

confidence: 76%

Mechanical and viscoelastic properties of confined amorphous polymers

Vogt

2017

J Polym Sci B Polym Phys

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“…52 Changes in the Young modulus upon confinement have also been reported in other studies. 52−56 Recently, Dequidt et al 57 made DPD simulations of the reinforcement of polymer films confined under strongly attractive substrates. They found thickness-dependent peaks in the plots of reinforcement vs temperature at temperatures above the bulk T g , which were attributed to the increased T g of the films due to the presence of the attractive surfaces.…”

Section: Introductionmentioning

confidence: 99%

Confinement-Induced Stiffening of Thin Elastomer Films: Linear and Nonlinear Mechanics vs Local Dynamics

2014

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Constant-pressure molecular-dynamics simulations have been carried out of a bead−rod model polymer confined between two attractive crystalline substrates. Three different substrate−substrate separations (i.e., film thicknesses) were used and two different polymer−substrate interaction strengths. The density profiles show a monomer layering close to the polymer− substrate interface. A higher density was found in this region compared to the middle bulklike layers of the films. The dependence of the film-averaged density on temperature and thickness was measured for all polymer films. Decreasing the film thickness leads to an increase of this density and of the film-averaged glass-transition temperature. Layer-resolved analysis of the segmental dynamics of the thickest films shows a gradient of the mobility upon approach of the polymer−substrate interface, while the middle-layer dynamics exhibits bulklike behavior. With decreasing film thickness, these gradients become overlapping. All polymer films were deformed uniaxially normal to the substrates beyond their linear viscoelastic regime; their elastic moduli but also their secant moduli at larger strain amplitudes were extracted. In the linear regime, the stiffness was found to increase with decreasing film thickness; this correlates well with the layer-resolved segmental dynamical behavior. A strong drop of the stiffness was observed upon increasing the deformation amplitude; this drop was more pronounced for stiffer films. It is shown that the drop in stiffness can be qualitatively explained by the drop of the relaxation times as well as by the increased heterogeneity of the dynamics in different film layers upon deformation. The thickness dependencies of the structural, dynamical, and mechanical properties become more pronounced with stronger adsorption to the substrates.

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“…Based on the relation for T g (z), the thickness of the glassy layer z th at temperature T can be estimated by T g (z th ) = T , i.e., z th = βT g,b / T − T g,b . The divergence in T g (z) is purely formal, since the physics which lead to this relation [50,51] has a natural cutoff at short distance of about 2 nm. The corresponding increase in the glass transition temperature, about 100 K at 2 nm in their system, corresponds to the increase of T g measured in [7], either in mechanical experiments or by using NMR.…”

Section: Relaxation Of Glassy Bridgesmentioning

confidence: 99%

“…In particular, the value we chose for the parameter β = 0.8 nm, which sets the amplitude of the T g -shift in the vicinity of the fillers, has been considered in [18], and corresponds to that measured experimentally in [6,7]. The only parameter that is slightly adapted from the many-particle simulations in [18][19][20] to our two-particle model is the stress sensitivity K in (51). In [18], K is determined such that, when imposing an oscillatory strain with amplitude 0.1 and rate 0.1 s −1 , the stress-induced shift of the glass transition temperature is 100 K at the maximum strain, which would result in K = 1.2 · 10 −20 J K −1 .…”

Section: Simulation Setupmentioning

confidence: 99%

“…However, in order to get better agreement between our model and the results in [20] (see further below), it was advantageous to choose the value K = 2 · 10 −20 J K −1 . In the simulations, the stress-induced shift in the glass transition temperature (51) has been limited to ≤200 K, since above that value the system is already plasticized (see also [19]). Finally, for numerical reasons, the range of the relaxation time (52) has been limited to 0.01 s ≤ τ α ≤ 100 s [20].…”

Section: Simulation Setupmentioning

confidence: 99%

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Concurrent two-scale model for the viscoelastic behavior of elastomers filled with hard nanoparticles

Semkiv

Long

Hütter

2016

Continuum Mech. Thermodyn.

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A dynamic two-scale model is developed for describing the mechanical behavior of elastomers filled with hard nanoparticles. Using nonequilibrium thermodynamics, a closed system of evolution equations is derived, coupling continuum mechanics with a fine-scale description on the level of filler particles. So doing, a constitutive stress-strain relation emerges that is applicable to transient situations. In addition to the number density of filler particles, the particle arrangement is captured by the distribution of the difference vector between two representative interacting particles, which makes this model efficient in comparison with manyparticle models. The two-particle model presented here is analyzed numerically in oscillatory deformation, for two purposes. First, the nonlinearity of the model is studied in detail, in terms of the Payne effect, that compares favorably with the literature. And second, the two-particle model is compared with a corresponding many-particle model in the literature.

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Mechanical properties of thin confined polymer films close to the glass transition in the linear regime of deformation: Theory and simulations

Cited by 48 publications

References 90 publications

Mechanical and viscoelastic properties of confined amorphous polymers

Mechanical and viscoelastic properties of confined amorphous polymers

Confinement-Induced Stiffening of Thin Elastomer Films: Linear and Nonlinear Mechanics vs Local Dynamics

Concurrent two-scale model for the viscoelastic behavior of elastomers filled with hard nanoparticles

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