Abstract
We report on the application of a Fourier transform-based method, 'i-Rheo', to evaluate the linear viscoelastic moduli of hard-sphere colloidal dispersions, both in the fluid and glass states, from a direct analysis of raw step-stress (creep) experimental data. We corroborate the efficacy of i-Rheo by comparing the outputs of creep tests performed on homogenous complex fluids to conventional dynamic frequency sweeps. A similar approach is adopted for a number of colloidal suspensions over a broad range of volume fractions. For these systems, we test the limits of the method by varying the applied stress across the materials' linear and non-linear viscoelastic regimes, and we show that the best results are achieved for stress values close to the upper limit of the materials' linear viscoelastic regime, where the signal-to-noise ratio is at its highest and the non-linear phenomena have not appeared yet. We record that, the range of accessible frequencies is controlled at the higher end by the relative weight between the inertia of the instrument and the elasticity of the complex material under investigation; whereas, the lowest accessible frequency is dictated by the extent of the materials' linear viscoelastic regime. Nonetheless, despite these constrains, we confirm the effectiveness of i-Rheo for gaining valuable information on the materials' linear viscoelastic properties even from 'creep ringing' data, confirming its potency and general validity as an accurate method for determining the material's rheological behaviour for a variety of complex systems.
Highlights
Paper validate the use of i-Rheo for the analysis of creep measurements performed on homogeneous complex fluids and we exploit it for the investigation of the linear viscoelastic (LVE) properties of hardsphere colloidal suspensions, over a broad range of colloidal volume fractions f including non-equilibrium glass states
The effectiveness of i-Rheo to evaluate the LVE properties of complex materials from conventional bulk rheology step-stress measurements has been initially corroborated by investigating the rheological properties of two homogeneous complex fluids (Section 4.1), applied to the rheological study of concentrated suspensions of colloidal particles, including glasses (Section 4.2)
4.3 Results of i-Rheo for different applied stresses In Fig. 8 we report the comparison between the frequencydependent linear viscoelastic moduli obtained by means of i-Rheo applied to the creep measurements shown in Fig. 7 and those obtained from a dynamic frequency sweeps (DFSs)
Summary
Validate the use of i-Rheo for the analysis of creep measurements performed on homogeneous complex fluids and we exploit it for the investigation of the LVE properties of hardsphere colloidal suspensions, over a broad range of colloidal volume fractions f including non-equilibrium glass states. We discuss the limits of the accessible range of frequencies for such systems, in particular in the non-equilibrium glass state, where non-homogeneous flows are observed for the majority of the experimental conditions
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
