We can't find the internet
Attempting to reconnect
Something went wrong!
Hang in there while we get back on track
Parametric Life Cycle Assessment of Chemical Recycling of Nylon-6 to Caprolactam
Summary
Researchers conducted the first life cycle assessment of four chemical recycling routes for converting waste nylon-6 back to its monomer caprolactam. The study found that a solvent-free alkaline process achieved approximately 80% reduction in global warming potential compared to fossil-based production, though none of the recycling routes fully met net-zero emission targets needed for limiting warming to 1.5 degrees Celsius.
Chemical recycling is gaining attention to advance the circular economy. This study presents the first life cycle assessment (LCA) of real-world waste polyamide 6 (PA6) remonomerization to caprolactam, evaluating four depolymerization routes: acidic, hydrothermal, alcoholysis, and alkaline. We established an automated Python-Aspen Plus-LCA workflow, systematically mapping variations in PA6 waste composition and key process parameters onto probability distributions of environmental impacts. Results show that the hydrothermal process has the highest impacts in six of nine categories, while the solvent-free, alkaline NaOH route consistently shows the lowest. Despite lower energy demands, the acidic H3PO4 process is not environmentally superior to the alcoholysis route. For the hydrothermal route, results are strongly driven by the water-to-feed ratio. However, its global warming potential (GWP) remains above that of fossil-based caprolactam. In contrast, the alcoholysis and acidic processes lower GWP by ∼35%, whereas the NaOH route achieves an ∼80% reduction to 1.46 kg CO2-eq/kg caprolactam. Although chemical recycling can mitigate impacts, no process consistently meets the net-zero emission carbon budget needed to limit global warming to 1.5 °C. As the NaOH process comes closest to this target and demonstrates the strongest environmental and economic performance, future research should focus on scaling-up solvent-free chemical recycling.
Sign in to start a discussion.
More Papers Like This
Life Cycle Analysis of a Novel Process from the Automotive Industry in Mexico for Recycling Nylon 6,6 into Polymeric Coatings
This study conducted a life cycle analysis of a novel process for recycling nylon 6,6 waste from the automotive industry in Mexico into polymeric coatings, evaluating the environmental impacts and sustainability benefits of this recycling approach.
Catalyst Design to Address Nylon Plastics Recycling
Researchers designed catalytic systems specifically targeting nylon-6 plastic recycling, addressing a major gap since nylon is a high-performance plastic with poor end-of-life recovery options. Better chemical recycling of nylons reduces the amount that persists in the environment as microplastic fibers from textiles and fishing gear.
Recycling of Plastics as a Strategy to Reduce Life Cycle GHG Emission, Microplastics and Resource Depletion
This study quantified the environmental benefits of recycling widely consumed plastic polymers, demonstrating that increased plastic recycling significantly reduces life cycle greenhouse gas emissions, microplastic pollution, and resource depletion.
Comparing the financial costs and carbon neutrality of polyester fibres produced from 100% bio-based PET, 100% recycled PET, or in combination
Researchers compared the financial costs and carbon footprint of producing polyester fibers from 100% bio-based sources versus enzymatic hydrolysis of recycled PET textiles, designing and simulating both production routes. The study found that the two approaches differ substantially in economic and environmental performance, with implications for sustainable fashion industry decisions.
Assessing the environmental footprint of recycled plastic pellets: A life-cycle assessment perspective
This study used life-cycle assessment to evaluate the environmental impact of producing recycled plastic pellets from waste polyolefin plastics. While recycling reduced carbon emissions compared to making new plastic, the process still required significant energy, especially when solvent recovery was maximized. The research is relevant to the microplastics problem because it shows that even recycling processes need optimization to truly reduce the environmental footprint of plastic waste.