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The Laplace approach in microrheology

Qi Li, Xiaoguang Peng, Dongjie Chen, Gregory B. McKenna

2020Soft Matter21 citationsDOI

Abstract

When coupled with the generalized Stokes-Einstein (GSE) equation, it is often reported that micro-rheology probes the dynamic properties differently than do macroscopic rheological measurements, especially in relatively condensed systems. In the present work, we empirically examine the GSE in its widely used form: following an analytical continuation, the Fourier transformed particle mean-square displacement (MSD) is used to determine the dynamic moduli [G'(ω) and G''(ω)] and we compare the results with those obtained by direct inverse Laplace transform calculation of the relevant viscoelastic functions (either relaxation modulus or creep compliance) from the MSD. The results show that the inverse Laplace approaches can differ from the Fourier approach and give better agreement with macroscopic rheological measurements when this is the case. Some instances of agreement between the Fourier approach and the direct Laplace transform approaches are also shown. It is recommended that micro-rheology MSD data be interpreted using one of the direct Laplace transform based approaches.

Topics & Concepts

Laplace transformMicrorheologyInverse Laplace transformRheologyViscoelasticityFourier transformRelaxation (psychology)InverseMean squared displacementDisplacement (psychology)Mathematical analysisMaterials scienceMathematicsPhysicsThermodynamicsGeometryMolecular dynamicsPsychotherapistSocial psychologyQuantum mechanicsPsychologyRheology and Fluid Dynamics StudiesMaterial Dynamics and PropertiesGranular flow and fluidized beds