Exploring the Nonlinear Rheology of Composite Hydrogels: A New Paradigm for LAOS Analysis

Abstract

We investigate composite biopolymer networks composed of co-polymerized fibrin and gelatin networks and perform rheological measurements over a broad parameter space including strain amplitudes that go beyond the linear response regime. One goal of the work presented here is to provide a prototypical biocomposite material with highly separable polymerization times and controlled nonlinear rheological characteristics. We then extend the Sequence of Physical Processes (SPP)Rogers2017 into a statistical and geometrical framework that fingerprints the nonlinear rheological response of biopolymer composite gels. Our analysis is based on the changes in the shape of the time-dependent Cole-Cole plots that allow to reduce the time resolved analysis of the SPP method into the transition between linear and nonlinear behavior as the rheological parameters are varied. While the results clearly highlight how the mechanical responses of individual constituents are not simply additive, our extended SPP analysis provides a robust and intuitive classification scheme for comparing the nonlinear response of composite materials subjected to large oscillatory strain.