Issue 33, 2019

Maximally stiffening composites require maximally coupled rather than maximally entangled polymer species

Abstract

Polymer composites are ideal candidates for next generation biomimetic soft materials because of their exquisite bottom-up designability. However, the richness of behaviours comes at a price: the need for precise and extensive characterisation of material properties over a highly-dimensional parameter space, as well as a quantitative understanding of the physical principles underlying desirable features. Here we couple large-scale Molecular Dynamics simulations with optical tweezers microrheology to characterise the viscoelastic response of DNA–actin composites. We discover that the previously observed non-monotonic stress-stiffening of these composites is robust, yet tunable, in a broad range of the parameter space that spans two orders of magnitude in DNA length. Importantly, we discover that the most pronounced stiffening is achieved when the species are maximally coupled, i.e., have similar number of entanglements, and not when the number of entanglements per DNA chain is largest. We further report novel dynamical oscillations of the microstructure of the composites, alternating between mixed and bundled phases, opening the door to future investigations. The generic nature of our system renders our results applicable to the behaviour of a broad class of polymer composites.

Graphical abstract: Maximally stiffening composites require maximally coupled rather than maximally entangled polymer species

Article information

Article type
Paper
Submitted
18 Jul 2019
Accepted
28 Jul 2019
First published
31 Jul 2019

Soft Matter, 2019,15, 6703-6717

Author version available

Maximally stiffening composites require maximally coupled rather than maximally entangled polymer species

D. Michieletto, R. Fitzpatrick and R. M. Robertson-Anderson, Soft Matter, 2019, 15, 6703 DOI: 10.1039/C9SM01461F

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