Sammanfattning
The design of lignin nanostructures where interfacial interactions enable enhanced entanglement of colloidal networks can broaden their applications in hydrogel-based materials and light-based 3D printing. Herein, an approach for fabricating surface-active dendritic colloidal microparticles (DCMs) characterized by fibrous structures using nanostructured allylated lignin is proposed for the development of lignin-based photocurable resins. With
allyl-terminated surface functionality of 0.61 mmol g−1, the entanglement between lignin-DCM fibrils with a size of 1.4 μm successfully produces only lignin-based hydrogels with structural integrity through photo-crosslinking. The colloidal network of lignin dendricolloids reinforces the poly(ethylene
glycol) (PEG) hydrogels during a digital light processing (DLP) 3D printing process by generating bicontinuous morphologies, resulting in six-fold
increases in toughness values with respect to the neat PEG hydrogel. The dual effectiveness of photoabsorption and free-radical reactivity of lignin-DCMs
allow the light-patterning of rather dilute PEG hydrogels (5–10%) with high geometric fidelity and structural complexity via DLP 3D printing. This study
demonstrates a green and effective strategy for the design of 1D lignin-DCMs that increases the versatility of the nanostructured biopolymer, opening up
numerous opportunities for formulating functional hydrogels with robust structure-property correlations.
allyl-terminated surface functionality of 0.61 mmol g−1, the entanglement between lignin-DCM fibrils with a size of 1.4 μm successfully produces only lignin-based hydrogels with structural integrity through photo-crosslinking. The colloidal network of lignin dendricolloids reinforces the poly(ethylene
glycol) (PEG) hydrogels during a digital light processing (DLP) 3D printing process by generating bicontinuous morphologies, resulting in six-fold
increases in toughness values with respect to the neat PEG hydrogel. The dual effectiveness of photoabsorption and free-radical reactivity of lignin-DCMs
allow the light-patterning of rather dilute PEG hydrogels (5–10%) with high geometric fidelity and structural complexity via DLP 3D printing. This study
demonstrates a green and effective strategy for the design of 1D lignin-DCMs that increases the versatility of the nanostructured biopolymer, opening up
numerous opportunities for formulating functional hydrogels with robust structure-property correlations.
Originalspråk | Engelska |
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Artikelnummer | 2315679 |
Tidskrift | Advanced Functional Materials |
Volym | 34 |
Nummer | 29 |
Tidigt onlinedatum | 21 mars 2024 |
DOI | |
Status | Publicerad - 21 mars 2024 |
MoE-publikationstyp | A1 Tidskriftsartikel-refererad |