Biochar Production From Plastic‐Contaminated Biomass

ABSTRACT Anaerobic digestion and composting of biowastes are vital pathways to recycle carbon and nutrients for agriculture. However, plastic contamination of soil amendments and fertilizers made from biowastes is a relevant source of (micro‐) plastics in (agricultural) ecosystems. To avoid this con...

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Veröffentlicht in:Global change biology. Bioenergy 2024-11, Vol.16 (11), p.n/a
Hauptverfasser: Hilber, Isabel, Hagemann, Nikolas, Rosa, José María, Knicker, Heike, Bucheli, Thomas D., Schmidt, Hans‐Peter
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Sprache:eng
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Zusammenfassung:ABSTRACT Anaerobic digestion and composting of biowastes are vital pathways to recycle carbon and nutrients for agriculture. However, plastic contamination of soil amendments and fertilizers made from biowastes is a relevant source of (micro‐) plastics in (agricultural) ecosystems. To avoid this contamination, plastic containing biowastes could be pyrolyzed to eliminate the plastic, recycle most of the nutrients, and create carbon sinks when the resulting biochar is applied to soil. Literature suggests plastic elimination mainly by devolatilization at co‐pyrolysis temperatures of > 520°C. However, it is uncertain if the presence of plastic during biomass pyrolysis induces the formation of organic contaminants or has any other adverse effects on biochar properties. Here, we produced biochar from wood residues (WR) obtained from sieving of biowaste derived digestate. The plastic content was artificially enriched to 10%, and this mixture was pyrolyzed at 450°C and 600°C. Beech wood (BW) chips and the purified, that is, (macro‐) plastic‐free WR served as controls. All biochars produced were below limit values of the European Biochar Certificate (EBC) regarding trace element content and organic contaminants. Under study conditions, pyrolysis of biowaste, even when contaminated with plastic, can produce a biochar suitable for agricultural use. However, thermogravimetric and nuclear magnetic resonance spectroscopic analysis of the WR + 10% plastics biochar suggested the presence of plastic residues at pyrolysis temperatures of 450°C. More research is needed to define minimum requirements for the pyrolysis of plastic containing biowaste and to cope with the automated identification and determination of plastic types in biowaste at large scales. Anaerobic digestion and composting of biowastes recycle carbon and nutrients for agriculture, but plastic contamination introduces microplastics into ecosystems. Pyrolysis can eliminate plastics and creates carbon sinks with biochar. This study produced biochar from wood residues with 10% plastic at 450°C and 600°C, compared to controls of beech wood and plastic‐free residues. All biochars met European Biochar Certificate limits for contaminants. However, 450°C pyrolysis left plastic residues, suggesting the need for higher temperatures and more research on pyrolysis requirements and plastic identification in biowastes.
ISSN:1757-1693
1757-1707
DOI:10.1111/gcbb.70005