TY - JOUR
T1 - Effects of Humidity on Mycelium-Based Leather
AU - Karunarathne, Ashoka
AU - Nabiyeva, Günel
AU - Rasmussen, Christopher J.
AU - Alkhoury, Keven
AU - Assem, Naila
AU - Bauer, Jonathan
AU - Chester, Shawn
AU - Khalizov, Alexei F.
AU - Gor, Gennady Y.
N1 - Publisher Copyright:
© 2024 American Chemical Society.
PY - 2024/10/21
Y1 - 2024/10/21
N2 - Leather is a product that has been used for millennia. While it is a natural material, its production raises serious environmental and ethical concerns. To mitigate those, the engineering of sustainable biobased leather substitutes has become a trend over the past few years. Among the biobased materials, mycelium, the fungal “root” of a mushroom, is one of the promising alternatives to animal leather, as a material with tunable physicomechanical properties. Understanding the effect of humidity on mycelium-based leather material properties is essential to the production of durable, competitive, and sustainable leather products. To this end, we measured the water sorption isotherms on several samples of mycelium-based leather materials and investigated the effects of water sorption on their elastic properties. The ultrasonic pulse transmission method was used to measure the wave speed through the materials while measuring their sorption isotherms at different humidity levels. Additionally, the material’s properties were mechanically tested by performing uniaxial tensile tests under ambient and immersed conditions. An overall reduction in elastic moduli was observed during both absorption and immersion. The changes in the measured longitudinal modulus during water sorption reveal changes in the elasticity of the test materials. The observed irreversible variation of the longitudinal modulus during the initial water sorption can be related to the material production process and the presence of various additives that affect the mechanical properties of the leather materials. Our results presented here should be of interest to material science experts developing a new generation of sustainable leather products.
AB - Leather is a product that has been used for millennia. While it is a natural material, its production raises serious environmental and ethical concerns. To mitigate those, the engineering of sustainable biobased leather substitutes has become a trend over the past few years. Among the biobased materials, mycelium, the fungal “root” of a mushroom, is one of the promising alternatives to animal leather, as a material with tunable physicomechanical properties. Understanding the effect of humidity on mycelium-based leather material properties is essential to the production of durable, competitive, and sustainable leather products. To this end, we measured the water sorption isotherms on several samples of mycelium-based leather materials and investigated the effects of water sorption on their elastic properties. The ultrasonic pulse transmission method was used to measure the wave speed through the materials while measuring their sorption isotherms at different humidity levels. Additionally, the material’s properties were mechanically tested by performing uniaxial tensile tests under ambient and immersed conditions. An overall reduction in elastic moduli was observed during both absorption and immersion. The changes in the measured longitudinal modulus during water sorption reveal changes in the elasticity of the test materials. The observed irreversible variation of the longitudinal modulus during the initial water sorption can be related to the material production process and the presence of various additives that affect the mechanical properties of the leather materials. Our results presented here should be of interest to material science experts developing a new generation of sustainable leather products.
KW - biobased leather
KW - elasticity
KW - plasticization
KW - ultrasonic testing
KW - water sorption
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U2 - 10.1021/acsabm.4c00586
DO - 10.1021/acsabm.4c00586
M3 - Article
C2 - 39383329
AN - SCOPUS:85206436067
SN - 2576-6422
VL - 7
SP - 6441
EP - 6450
JO - ACS Applied Bio Materials
JF - ACS Applied Bio Materials
IS - 10
ER -