Integrating durability-based service-life predictions with environmental impact assessments of natural fiber–reinforced composite materials

Abstract As concern about resource conservation has grown, research efforts have increased to develop materials out of rapidly renewable constituents, to assess their life cycle environmental impacts, and to predict their service-life performance. Assessing time-dependent material property deterioration, often a concern for polymers and their composites, is essential to evaluating the viability of novel materials to serve as lower environmental impact replacements for conventional materials. However, research in methods to combine environmental impacts from production and material deterioration is limited. In this research, a durability-based service-life model was used to assess and incorporate composite deterioration into life cycle environmental impact analyses. The inclusion of composite deterioration under differing temperature and moisture conditions in these analyses typically resulted in higher volumes of material needed to serve the desired function compared to volumes needed to satisfy initial design requirements, leading to a change in environmental impact. While this concept falls in line with the classic definition of material efficiency, namely improving mass yield for materials, the results of the life cycle impact assessment showed with certain process modifications lower environmental impacts could be achieved even in cases where more material was being used. These findings indicate that design decisions must account for application-specific requirements and consider environmental impacts concurrently with material deterioration.

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