Life Cycle Assessment of Bioplastics and Food Waste Disposal Methods

The environmental impacts of five waste management scenarios for polylactic acid (PLA)-based bioplastics and food waste were quantified using life cycle assessment. Laboratory experiments have demonstrated the potential for a pretreatment process to accelerate the degradation of bioplastics and were modeled in two of the five scenarios assessed. The five scenarios analyzed in this study were: (1a) Anaerobic digestion (1b) Anaerobic digestion with pretreatment; (2a) Compost; (2a) Compost with pretreatment; (3) Landfill. Results suggested that food waste and pretreated bioplastics disposed of with an anaerobic digester offers life cycle and environmental net total benefits (environmental advantages/offsets) in several areas: ecotoxicity (-81.38 CTUe), eutrophication (0 kg N eq), cumulative energy demand (-1.79 MJ), global warming potential (0.19 kg CO2), and human health non-carcinogenic (-2.52 CTuh). Normalized results across all impact categories show that anaerobically digesting food waste and bioplastics offer the most offsets for ecotoxicity, eutrophication, cumulative energy demand and non-carcinogenic. Implications from this study can lead to nutrient and energy recovery from an anaerobic digester that can diversify the types of fertilizers and decrease landfill waste while decreasing dependency on non-renewable technologies. Thus, using anaerobic digestion to manage bioplastics and food waste should be further explored as a viable and sustainable solution for waste management.

Automated summary

The study found that using anaerobic digestion to process food waste and bioplastics can provide overall life cycle and environmental benefits, including reducing ecotoxicity, eutrophication, cumulative energy demand, and non-carcinogenic effects. Therefore, energy and nutrient recovery through anaerobic digestion of these wastes is a feasible and sustainable waste management solution that should be further explored.