| Title |
Double-interpenetrating nanostructured networks of marine polysaccharides possessing properties comparable to synthetic polymers |
| ID_Doc |
21433 |
| Authors |
Ghrissi, F; Gu, YW; Shastri, VP |
| Title |
Double-interpenetrating nanostructured networks of marine polysaccharides possessing properties comparable to synthetic polymers |
| Year |
2022 |
| Published |
Proceedings Of The National Academy Of Sciences Of The United States Of America, 119.0, 42 |
| DOI |
10.1073/pnas.2204073119 |
| Abstract |
Sustainable circular economy requires materials that possess a property profile compara-ble to synthetic polymers and, additionally, processing and sourcing of raw materials that have a small environmental footprint. Here, we present a paradigm for processing marine biopolymers into materials that possess both elastic and plastic behavior within a single system involving a double-interpenetrating polymer network comprising the elas-tic phase of dynamic physical cross-links and stress-dissipating ionically cross-linked domains. As a proof of principle, films possessing more than twofold higher elastic mod-ulus, ultimate tensile strength, and yield stress than those of polylactic acid were realized by blending two water-soluble marine polysaccharides, namely alginic acid (Alg) with physically cross-linkable carboxylated agarose (CA) followed by ionic cross-linking with a divalent cation. Dried CAAlg films showed homogeneous nano-micro-scale domains, with yield stress and size of the domains scaling inversely with calcium concentration. Through surface activation/cross-linking using calcium, CAAlg films could be further processed using wet bonding to yield laminated structures with interfacial failure loads (13.2 +/- 0.81 N) similar to the ultimate loads of unlaminated films (10.09 +/- 1.47 N). Toward the engineering of wood-marine biopolymer composites, an array of lines of CAAlg were printed on wood veneers (panels), dried, and then bonded following activa-tion with calcium to yield fully bonded wood two-ply laminate. The system presented herein provides a blueprint for the adoption of marine algae-derived polysaccharides in the development of sustainable high-performance materials. |
| Author Keywords |
circular economy; bio-nanocomposite; double-interpenetrating network; nanostructured domains; 3D printing |
| Index Keywords |
Index Keywords |
| Document Type |
Other |
| Open Access |
Open Access |
| Source |
Science Citation Index Expanded (SCI-EXPANDED) |
| EID |
WOS:000998758000010 |
| WoS Category |
Multidisciplinary Sciences |
| Research Area |
Science & Technology - Other Topics |
| PDF |
https://doi.org/10.1073/pnas.2204073119
|