M. Seredyńska scite author profile

The results obtained previously for scalar and class P completely monotone relaxation moduli are extended to arbitrary anisotropy. It is shown for general anisotropic viscoelastic media that, if the relaxation modulus is a locally integrable completely monotone function, then the creep compliance is a Bernstein function and conversely. The elastic and equilibrium limits of the two material functions are related to each other. The relaxation modulus or its derivative can be singular at 0. A rigorous general formulation of the relaxation spectrum in an anisotropic viscoelastic medium is given. The effect of Newtonian viscosity on creep compliance is examined. Notation d space dimension; D = d(d + 1)/2; S the linear space of symmetric d × d matrices; G the set of symmetric operators on S; T d the set of linear transformations of a d-dimensional vector space V d ; A. Hanyga (B) 42 A. Hanyga, M. Seredyńska I unit operator on S; A transpose of A; v A w = v k A kl w l ; v, F w := v kl F klpq w pq ; R + =]0, ∞[, R + = [0, ∞[; C + := {z ∈ C | Im z > 0}; C − := C\ ] − ∞, 0]; L p (A; V) the space of measurable functions f : A → V with | f | p ∈ L 1 (A; R + ); M(A; V) the set of positive Radon measures on A with values in V; M + (A; T d ) the set of Radon measures on A with values in T d ; |H|(E) total variation of a Radon measure H ∈ M(A; V); σ, σ1D stress, stress tensor; e, e scalar strain, strain tensor; g, j scalar relaxation modulus and creep compliance; G, J tensorial relaxation modulus and creep compliance.

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Anisotropy in high-resolution diffusion-weighted MRI and anomalous diffusion

Hanyga¹,

Seredyńska²

2012

Journal of Magnetic Resonance

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Asymptotic and exact fundamental solutions in hereditary media with singular memory kernels

Hanyga¹,

Seredyńska²

2002

Quart. Appl. Math.

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Relaxation, dispersion, attenuation, and finite propagation speed in viscoelastic media

Seredyńska

Hanyga

2010

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It is shown that the dispersion and attenuation functions in a linear viscoelastic medium with a positive relaxation spectrum can be expressed in terms of a positive measure. Both functions have a sublinear growth rate at very high frequencies.In the case of power law attenuation positive relaxation spectrum ensures finite propagation speed. For more general attenuation functions the requirement of finite propagation speed imposes a more stringent condition on the high-frequency behavior of attenuation. It is demonstrated that superlinear power law frequency dependence of attenuation is incompatible with finite speed of propagation and with the assumption of positive relaxation spectrum.

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M. Seredyńska

Relations Between Relaxation Modulus and Creep Compliance in Anisotropic Linear Viscoelasticity

Anisotropy in high-resolution diffusion-weighted MRI and anomalous diffusion

Asymptotic and exact fundamental solutions in hereditary media with singular memory kernels

Relaxation, dispersion, attenuation, and finite propagation speed in viscoelastic media

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