In the context of sustainable materials for outdoor applications, the use of bio-based and biodegradable composites reinforced with agro-industrial waste represents a promising strategy. However, exposure to sunlight and oxygen can lead to photo-oxidation, potentially compromising both performance and biodegradability. In this study, Mater-Bi (MB) was compounded with 10 and 20 wt% grape pomace (GP), a by-product rich in polyphenols, and the resulting biocomposites were subjected to accelerated aging. The impact of photo-oxidation was evaluated through rheological, thermal, and mechanical analyses, alongside biodegradation tests in soil. The results revealed that while neat MB undergoes significant degradation upon aging, the GP-filled composites exhibited better resistance to photo-oxidative damage. Importantly, the biodegradation behaviour of the aged samples was also investigated, highlighting how prior oxidative degradation influences the subsequent disintegration of the material in a natural environment. The findings underscore the importance of assessing the end-of-life performance of biocomposites after environmental weathering, to ensure their sustainability under real-life outdoor conditions.
Rapisarda, M., Titone, V., Pulvirenti, L., Napoli, E., Impallomeni, G., Botta, L., et al. (2025). Insights into the accelerated aging of sustainable biocomposites based on Mater-Bi and grape pomace. POLYMER DEGRADATION AND STABILITY, 241 [10.1016/j.polymdegradstab.2025.111551].
Insights into the accelerated aging of sustainable biocomposites based on Mater-Bi and grape pomace
Titone V.;Botta L.;Mistretta M. C.
2025-11-01
Abstract
In the context of sustainable materials for outdoor applications, the use of bio-based and biodegradable composites reinforced with agro-industrial waste represents a promising strategy. However, exposure to sunlight and oxygen can lead to photo-oxidation, potentially compromising both performance and biodegradability. In this study, Mater-Bi (MB) was compounded with 10 and 20 wt% grape pomace (GP), a by-product rich in polyphenols, and the resulting biocomposites were subjected to accelerated aging. The impact of photo-oxidation was evaluated through rheological, thermal, and mechanical analyses, alongside biodegradation tests in soil. The results revealed that while neat MB undergoes significant degradation upon aging, the GP-filled composites exhibited better resistance to photo-oxidative damage. Importantly, the biodegradation behaviour of the aged samples was also investigated, highlighting how prior oxidative degradation influences the subsequent disintegration of the material in a natural environment. The findings underscore the importance of assessing the end-of-life performance of biocomposites after environmental weathering, to ensure their sustainability under real-life outdoor conditions.
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