Fracture and Toughening of Mycelium-based Biocomposites
Date
2024
Authors
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Journal ISSN
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Publisher
Materials & Design
Abstract
This study presents a combined experimental and analytical study of the fracture behavior and toughening
mechanisms of bioprocessed mycelium-based biocomposites. The composites comprise hemicellulose hemp ducts
(as nutritional and reinforcing components) intertwined with increasing weight percentages of laterite particles.
Single-edge notched fracture experiments and in-situ observations of crack growth were used to explore the ef fects of varying proportions of laterite on the composite resistance-curve behavior. The toughening mechanisms,
fracture modes, and crack-microstructure interactions were also elucidated. Since crack-bridging and crack deflection were observed to be the dominant toughening mechanisms, they were modeled using fracture me chanics approaches. Crack-bridging was shown to dominate the toughening at lower weight fractions of laterite
(0–20 wt%). However, as the laterite content increases (20–40 wt%), a combination of crack-bridging and crack deflection was observed. Finally, at higher laterite weight fractions (>40 wt%), crack-tip shielding occurred
primarily via crack deflection. The fracture mechanics predictions of resistance-curve behavior are shown to be
consistent with the experimental measurements. The results suggest that mycelium-based and mycelium-laterite
composites can be engineered with tunable fracture toughness. The implications of the results are also discussed
for the development of sustainable building materials.
Description
Research Article
Keywords
Crack-microstructure interactions, Fracture mechanics, Fracture modes