Anaerobic digestion of wastewater from hydrothermal liquefaction of sewage sludge and combined wheat straw-manure

Williane Vieira Macêdo; Rune Dall Harpøth; Jan Struckmann Poulsen; Nadieh de Jonge; Christian Holst Fischer; Laura M Agneessens; Jeppe Lund Nielsen; Patrick Biller; Caroline Kragelund Rickers; Leendert Vergeynst

doi:10.1016/j.biortech.2024.130559

Anaerobic digestion of wastewater from hydrothermal liquefaction of sewage sludge and combined wheat straw-manure

Williane Vieira Macêdo, Rune Dall Harpøth, Jan Struckmann Poulsen, Nadieh de Jonge, Christian Holst Fischer, Laura M Agneessens, Jeppe Lund Nielsen, Patrick Biller, Caroline Kragelund Rickers, Leendert Vergeynst

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Abstract

Hydrothermal liquefaction (HTL) shows promise for converting wet biomass waste into biofuel, but the resulting high-strength process water (PW) requires treatment. This study explored enhancing energy recovery by anaerobic digestion using semi-batch reactors. Co-digesting manure with HTL-PW from wheat straw-manure co-HTL yielded methane (43-49% of the chemical oxygen demand, COD) at concentrations up to 17.8 gCOD·L -1, whereas HTL-PW from sewage sludge yielded methane (43% of the COD) up to only 12.8 gCOD·L -1 and complete inhibition occurred at 17 gCOD·L -1. Microbial community shifts confirmed inhibition of methanogenic archaea, while hydrolytic-fermentative bacteria were resilient. Differences in chemical composition, particularly higher levels of N-containing heterocyclic compounds in PW of sewage sludge, likely caused the microbial inhibition. The considerable potential of combining HTL with anaerobic digestion for enhanced energy recovery from straw-manure in an agricultural context is demonstrated, yet sewage sludge HTL-PW requires more advanced approaches to deal with methanogenesis inhibitors.

Original language	English
Article number	130559
Journal	Bioresource Technology
Volume	399
ISSN	0960-8524
DOIs	https://doi.org/10.1016/j.biortech.2024.130559
Publication status	Published - May 2024

Bibliographical note

Keywords

Biogas
Heterocyclic compounds
Inhibition
Methane yield
Microbial community

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10.1016/j.biortech.2024.130559Licence: CC BY 4.0

Open Access ArticleFinal published version, 3.14 MBLicence: CC BY 4.0

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Macêdo, W. V., Harpøth, R. D., Poulsen, J. S., de Jonge, N., Fischer, C. H., Agneessens, L. M., Nielsen, J. L., Biller, P., Rickers, C. K., & Vergeynst, L. (2024). Anaerobic digestion of wastewater from hydrothermal liquefaction of sewage sludge and combined wheat straw-manure. Bioresource Technology, 399, Article 130559. https://doi.org/10.1016/j.biortech.2024.130559

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title = "Anaerobic digestion of wastewater from hydrothermal liquefaction of sewage sludge and combined wheat straw-manure",

abstract = "Hydrothermal liquefaction (HTL) shows promise for converting wet biomass waste into biofuel, but the resulting high-strength process water (PW) requires treatment. This study explored enhancing energy recovery by anaerobic digestion using semi-batch reactors. Co-digesting manure with HTL-PW from wheat straw-manure co-HTL yielded methane (43-49% of the chemical oxygen demand, COD) at concentrations up to 17.8 gCOD·L -1, whereas HTL-PW from sewage sludge yielded methane (43% of the COD) up to only 12.8 gCOD·L -1 and complete inhibition occurred at 17 gCOD·L -1. Microbial community shifts confirmed inhibition of methanogenic archaea, while hydrolytic-fermentative bacteria were resilient. Differences in chemical composition, particularly higher levels of N-containing heterocyclic compounds in PW of sewage sludge, likely caused the microbial inhibition. The considerable potential of combining HTL with anaerobic digestion for enhanced energy recovery from straw-manure in an agricultural context is demonstrated, yet sewage sludge HTL-PW requires more advanced approaches to deal with methanogenesis inhibitors. ",

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year = "2024",

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doi = "10.1016/j.biortech.2024.130559",

language = "English",

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AU - de Jonge, Nadieh

AU - Fischer, Christian Holst

AU - Agneessens, Laura M

AU - Nielsen, Jeppe Lund

AU - Biller, Patrick

AU - Rickers, Caroline Kragelund

AU - Vergeynst, Leendert

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N2 - Hydrothermal liquefaction (HTL) shows promise for converting wet biomass waste into biofuel, but the resulting high-strength process water (PW) requires treatment. This study explored enhancing energy recovery by anaerobic digestion using semi-batch reactors. Co-digesting manure with HTL-PW from wheat straw-manure co-HTL yielded methane (43-49% of the chemical oxygen demand, COD) at concentrations up to 17.8 gCOD·L -1, whereas HTL-PW from sewage sludge yielded methane (43% of the COD) up to only 12.8 gCOD·L -1 and complete inhibition occurred at 17 gCOD·L -1. Microbial community shifts confirmed inhibition of methanogenic archaea, while hydrolytic-fermentative bacteria were resilient. Differences in chemical composition, particularly higher levels of N-containing heterocyclic compounds in PW of sewage sludge, likely caused the microbial inhibition. The considerable potential of combining HTL with anaerobic digestion for enhanced energy recovery from straw-manure in an agricultural context is demonstrated, yet sewage sludge HTL-PW requires more advanced approaches to deal with methanogenesis inhibitors.

AB - Hydrothermal liquefaction (HTL) shows promise for converting wet biomass waste into biofuel, but the resulting high-strength process water (PW) requires treatment. This study explored enhancing energy recovery by anaerobic digestion using semi-batch reactors. Co-digesting manure with HTL-PW from wheat straw-manure co-HTL yielded methane (43-49% of the chemical oxygen demand, COD) at concentrations up to 17.8 gCOD·L -1, whereas HTL-PW from sewage sludge yielded methane (43% of the COD) up to only 12.8 gCOD·L -1 and complete inhibition occurred at 17 gCOD·L -1. Microbial community shifts confirmed inhibition of methanogenic archaea, while hydrolytic-fermentative bacteria were resilient. Differences in chemical composition, particularly higher levels of N-containing heterocyclic compounds in PW of sewage sludge, likely caused the microbial inhibition. The considerable potential of combining HTL with anaerobic digestion for enhanced energy recovery from straw-manure in an agricultural context is demonstrated, yet sewage sludge HTL-PW requires more advanced approaches to deal with methanogenesis inhibitors.

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KW - Heterocyclic compounds

KW - Inhibition

KW - Methane yield

KW - Microbial community

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DO - 10.1016/j.biortech.2024.130559

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JO - Bioresource Technology

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Anaerobic digestion of wastewater from hydrothermal liquefaction of sewage sludge and combined wheat straw-manure

Abstract

Bibliographical note

Keywords

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