Communications Materials (Sep 2024)

Self-assembly of sustainable plant protein protofilaments into a hydrogel for ultra-low friction across length scales

  • Olivia Pabois,
  • Yihui Dong,
  • Nir Kampf,
  • Christian D. Lorenz,
  • James Doutch,
  • Alejandro Avila-Sierra,
  • Marco Ramaioli,
  • Mingduo Mu,
  • Yasmin Message,
  • Evangelos Liamas,
  • Arwen I. I. Tyler,
  • Jacob Klein,
  • Anwesha Sarkar

DOI
https://doi.org/10.1038/s43246-024-00590-5
Journal volume & issue
Vol. 5, no. 1
pp. 1 – 13

Abstract

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Abstract Designing plant protein-based aqueous lubricants can be of great potential to achieve sustainability objectives by capitalising on inherent functional groups without using synthetic chemicals; however, such a concept remains in its infancy. Here, we engineer a class of self-assembled sustainable materials by using plant-based protofilaments and their assembly within a biopolymeric hydrogel giving rise to a distinct patchy architecture. By leveraging physical interactions, this material offers superlubricity with friction coefficients of 0.004-to-0.00007 achieved under moderate-to-high (102-to-103 kPa) contact pressures. Multiscale experimental measurements combined with molecular dynamics simulations reveal an intriguing synergistic mechanism behind such ultra-low friction - where the uncoated areas of the protofilaments glue to the surface by hydrophobic interactions, whilst the hydrogel offers the hydration lubrication. The current approach establishes a robust platform towards unlocking an untapped potential of using plant protein-based building blocks across diverse applications where achieving superlubricity and environmental sustainability are key performance indicators.