High-efficient microwave plasma discharging initiated conversion of waste plastics into hydrogen and carbon nanotubes

Large-scale manufacture and discard of plastics cause ever serious white pollution. Chemical recycling has been identified as a promising method to convert waste plastics into fuels and chemical products. In this work, a simple and high-efficient method initiated by microwave plasma discharging is proposed to decompose plastics into hydrogen and carbon nanotubes, wherein iron-based catalysts are used as the microwave susceptor and metal tips are utilized to induce plasma discharging. Iron-based catalysts supported on activated carbons cal-cinated at 400 degrees C have displayed the best catalytic activity due to the excellent physicochemical properties. Massive H-2 rapidly evolves out in the 25 s with a hydrogen efficiency of over 85%. The yield of H-2 with plasma discharging by using Fe/AC-400 catalyst is near 300 mmol.g(-1)H(plastic), which exhibits a 6 times improvement compared to 41 mmol.g(-1)H(plastic) without plasma discharging by using AC catalyst. Little other gases including CH4, CO and CO2 are detected while high-value carbon nanotubes are fabricated. The continuity test over Fe/AC-400 catalyst with microwave plasma discharging presents the distinct ability to generate CNTs continuously. The decomposition for three kinds of plastics has demonstrated the extremely high universal and potential in prac-tical application for real-world plastic wastes.

Automated summary

This study proposes an efficient method initiated by microwave plasma discharging to decompose plastics into hydrogen and carbon nanotubes. The use of iron-based catalysts on activated carbons achieves the best catalytic activity.