Abstract
We report that aqueous solutions of high molecular weight chitosan display a regime of shear thinning at low shear rates that is consistent with the existence of an apparent yield stress. The concentration-dependent scaling of the apparent yield stress, σ0(c)~c2.8±0.2 in the concentration range c = 7.50–65.0 mg/mL, is consistent with a solution microstructure of fractal clusters. Dynamic light scattering measurements at high concentration indicate extremely slow microdynamics, consistent with the presence of a structured network or glassy fluid. At shear rates above yielding, a constant viscosity plateau was observed with concentration-dependent scaling below the gel point consistent with existing models of entangled and associating polymers. The addition of urea, a hydrogen bond and hydrophobic interaction disrupter, did not change the reported concentration-dependent scaling of the apparent yield stress or the plateau viscosity but did weaken the apparent yield stress magnitude by ~ 30% on average.
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Acknowledgments
The authors acknowledge Anton Paar for the availability of the MCR 702 Twin Drive rheometer through an instrument loan program.
Funding
Financial support for this research was provided by NSF (grant number NSF DMR 1408817).
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Gasbarro, N.M., Solomon, M.J. Yield stress and rheology of a self-associating chitosan solution. Rheol Acta 58, 729–739 (2019). https://doi.org/10.1007/s00397-019-01173-9
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DOI: https://doi.org/10.1007/s00397-019-01173-9