Structural control of elastic moduli in ferrogels and the importance of non-affine deformations

Pessot, Giorgio; Cremer, Peet; Borin, Dmitry; Odenbach, Stefan; Löwen, Hartmut; Menzel, Andreas M.

doi:10.1063/1.4896147

Cited by 59 publications

(69 citation statements)

References 58 publications

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“…However, the nature of the mechanical response and other characteristic material properties can strongly depend on the spatial distribution of the magnetic particles within the sample. 1,31,[44][45][46][47][48][49][50][51] Typical particle diameters range from nano-to micrometers and thus involve an intermediate, i.e., mesoscopic length scale. Finally, for rubbery substances, the fact that the materials are elastic mainly results from the entropic properties of the single crosslinked polymer chains and is therefore of molecular microscopic origin.…”

Section: Introductionmentioning

confidence: 99%

Bridging from particle to macroscopic scales in uniaxial magnetic gels

Menzel

2014

The Journal of Chemical Physics

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Connecting the different length scales of characterization is an important, but often very tedious task for soft matter systems. Here, we carry out such a procedure for the theoretical description of anisotropic uniaxial magnetic gels. The so-far undetermined material parameters in a symmetry-based macroscopic hydrodynamic-like description are determined starting from a simplified mesoscopic particle-resolved model. This mesoscopic approach considers chain-like aggregates of magnetic particles embedded in an elastic matrix. Our procedure provides an illustrative background to the formal symmetry-based macroscopic description. There are presently other activities to connect such mesoscopic models as ours with more microscopic polymer-resolved approaches; together with these activities, our study complements a first attempt of scale-bridging from the microscopic to the macroscopic level in the characterization of magnetic gels.

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Section: Introductionmentioning

confidence: 99%

Bridging from particle to macroscopic scales in uniaxial magnetic gels

Menzel

2014

The Journal of Chemical Physics

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“…41 Ferrofluids 42 and ferrogels [43][44][45] (for a recent review see Ref. 46) with magnetic particles provide further prominent examples of smart materials where anisotropic particles are involved.…”

Section: Introductionmentioning

confidence: 99%

Depolarized light scattering from prolate anisotropic particles: The influence of the particle shape on the field autocorrelation function

Passow

Hagen

Löwen

et al. 2015

The Journal of Chemical Physics

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We provide a theoretical analysis for the intermediate scattering function typically measured in depolarized dynamic light scattering experiments. We calculate the field autocorrelation function g1(VH)(Q,t) in dependence on the wave vector Q and the time t explicitly in a vertical-horizontal scattering geometry for differently shaped solids of revolution. The shape of prolate cylinders, spherocylinders, spindles, and double cones with variable aspect ratio is expanded in rotational invariants flm(r). By Fourier transform of these expansion coefficients, a formal multipole expansion of the scattering function is obtained, which is used to calculate the weighting coefficients appearing in the depolarized scattering function. In addition to translational and rotational diffusion, especially the translational-rotational coupling of shape-anisotropic objects is considered. From the short-time behavior of the intermediate scattering function, the first cumulants Γ(Q) are calculated. In a depolarized scattering experiment, they deviate from the simple proportionality to Q(2). The coefficients flm(Q) strongly depend on the geometry and aspect ratio of the particles. The time dependence, in addition, is governed by the translational and rotational diffusion tensors, which are calculated by means of bead models for differently shaped particles in dependence on their aspect ratio. Therefore, our analysis shows how details of the particle shape--beyond their aspect ratio--can be determined by a precise scattering experiment. This is of high relevance in understanding smart materials which involve suspensions of anisotropic colloidal particles.

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“…This may be exploited in constructing novel damping devices [10] and vibrational absorbers [11]. Several theoretical studies have shown that the internal spatial particle distribution plays a qualitative role for this effect [12][13][14][15]. Furthermore, applying time-dependent external magnetic fields can induce deformations, which makes the materials candidates for the use as soft actuators [5,16,17].…”

Section: Introductionmentioning

confidence: 99%

Tunable dynamic response of magnetic gels: Impact of structural properties and magnetic fields

et al. 2014

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Ferrogels and magnetic elastomers feature mechanical properties that can be reversibly tuned from outside through magnetic fields. Here we concentrate on the question how their dynamic response can be adjusted. The influence of three factors on the dynamic behavior is demonstrated using appropriate minimal models: first, the orientational memory imprinted into one class of the materials during their synthesis; second, the structural arrangement of the magnetic particles in the materials; and third, the strength of an external magnetic field. To illustrate the latter point, structural data are extracted from a real experimental sample and analyzed. Understanding how internal structural properties and external influences impact the dominant dynamical properties helps to design materials that optimize the requested behavior.

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Structural control of elastic moduli in ferrogels and the importance of non-affine deformations

Cited by 59 publications

References 58 publications

Bridging from particle to macroscopic scales in uniaxial magnetic gels

Bridging from particle to macroscopic scales in uniaxial magnetic gels

Depolarized light scattering from prolate anisotropic particles: The influence of the particle shape on the field autocorrelation function

Tunable dynamic response of magnetic gels: Impact of structural properties and magnetic fields

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