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Synergising hydrothermal pre-treatment and biological processes for enhancing biohydrogen production from palm oil mill effluent

The high quantity of nutrient-rich palm oil mill effluent (POME) waste in the industry will have a severe negative environmental impact and a high cost of treatment. However, POME waste could be converted into bioenergy via environmentally sustainable processes. Several studies have explored using h...

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Main Authors: Zainal B.S., Yu K.L., Ong H.C., Mohamed H., Ker P.J., Abdulkreem-Alsultan G., Taufiq-Yap Y.H., Mahlia T.I.
Other Authors: 57200914760
Format: Article
Published: Institution of Chemical Engineers 2025
Subjects:
Chemical oxygen demand
Clostridium
Effluent treatment
Exhaust gases
Explosive well stimulation
Film preparation
Land fill
Layered manufacturing
Mining laws and regulations
Oil shale
Quality assurance
Quality control
Room and pillar mining
Bio-hydrogen
Bio-hydrogen production
Biological treatment
Dark fermentation
Hydrothermal
Hydrothermal process
Palm oil mill effluents
Palm oil wastes
Substrate pretreatment
Sustainable energy
Effluents
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spelling my.uniten.dspace-360792025-03-03T15:41:21Z Synergising hydrothermal pre-treatment and biological processes for enhancing biohydrogen production from palm oil mill effluent Zainal B.S. Yu K.L. Ong H.C. Mohamed H. Ker P.J. Abdulkreem-Alsultan G. Taufiq-Yap Y.H. Mahlia T.I. 57200914760 57539404500 55310784800 57136356100 37461740800 59154538800 57194506693 56997615100 Chemical oxygen demand Clostridium Effluent treatment Exhaust gases Explosive well stimulation Film preparation Land fill Layered manufacturing Mining laws and regulations Oil shale Quality assurance Quality control Room and pillar mining Bio-hydrogen Bio-hydrogen production Biological treatment Dark fermentation Hydrothermal Hydrothermal process Palm oil mill effluents Palm oil wastes Substrate pretreatment Sustainable energy Effluents The high quantity of nutrient-rich palm oil mill effluent (POME) waste in the industry will have a severe negative environmental impact and a high cost of treatment. However, POME waste could be converted into bioenergy via environmentally sustainable processes. Several studies have explored using hydrothermal carbonisation for solid biomass products in biofuel production, but the potential of the liquid phase produced during these processes has received less attention. Therefore, this study aims to assess the potential of biohydrogen production from treated POME as a substrate by hydrothermal process. This study is presented in two phases: the first phase involves substrate pre-treatment using a hydrothermal process to improve biomass properties at different temperatures, and the second phase explores the potential for biohydrogen production from treated POME through dark fermentation. Substrate pre-treatment was conducted at 180, 210, and 240 �C using 100 % raw POME. Next, the treated POME was incubated for biohydrogen production at 50 �C for 24 h. A microbial analysis was conducted to determine the most dominant species present in the sample. Our findings show that at 180 �C, the total chemical oxygen demand (COD) removal efficiency was 80 %, and acetic acid concentration was 28 %. Compared to raw POME, treated POME generated a maximum hydrogen yield and rate (HPR) of 52.19 mL H2 g?1 CODrem and 0.59 mL H2 mL POME?1 day?1 with a 2.32-fold and 1.59-fold increase, respectively. Meanwhile, Clostridium was a dominant bacterial species identified in the treated POME. These findings demonstrated the feasibility of implementing a hydrothermal process to treat POME and improve its biohydrogen production efficiency. The treated POME from the hydrothermal process is more homogenous and readily consumable by microorganisms used in dark fermentation. Hydrothermal pre-treatment could potentially increase the rate and efficiency of microbial digestion, leading to enhanced hydrogen production. The high COD removal efficiency during the process significantly reduces the environmental impact of POME discharge, and converting POME into a valuable resource through the hydrothermal and dark fermentation process aligns with sustainable waste management practices. ? 2024 The Institution of Chemical Engineers Final 2025-03-03T07:41:21Z 2025-03-03T07:41:21Z 2024 Article 10.1016/j.psep.2024.10.024 2-s2.0-85207027732 https://www.scopus.com/inward/record.uri?eid=2-s2.0-85207027732&doi=10.1016%2fj.psep.2024.10.024&partnerID=40&md5=096ee060bd3235649bef86264fc0d8d6 https://irepository.uniten.edu.my/handle/123456789/36079 192 424 436 Institution of Chemical Engineers Scopus
institution Universiti Tenaga Nasional
building UNITEN Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Tenaga Nasional
content_source UNITEN Institutional Repository
url_provider http://dspace.uniten.edu.my/
topic Chemical oxygen demand
Clostridium
Effluent treatment
Exhaust gases
Explosive well stimulation
Film preparation
Land fill
Layered manufacturing
Mining laws and regulations
Oil shale
Quality assurance
Quality control
Room and pillar mining
Bio-hydrogen
Bio-hydrogen production
Biological treatment
Dark fermentation
Hydrothermal
Hydrothermal process
Palm oil mill effluents
Palm oil wastes
Substrate pretreatment
Sustainable energy
Effluents
spellingShingle Chemical oxygen demand
Clostridium
Effluent treatment
Exhaust gases
Explosive well stimulation
Film preparation
Land fill
Layered manufacturing
Mining laws and regulations
Oil shale
Quality assurance
Quality control
Room and pillar mining
Bio-hydrogen
Bio-hydrogen production
Biological treatment
Dark fermentation
Hydrothermal
Hydrothermal process
Palm oil mill effluents
Palm oil wastes
Substrate pretreatment
Sustainable energy
Effluents
Zainal B.S.
Yu K.L.
Ong H.C.
Mohamed H.
Ker P.J.
Abdulkreem-Alsultan G.
Taufiq-Yap Y.H.
Mahlia T.I.
Synergising hydrothermal pre-treatment and biological processes for enhancing biohydrogen production from palm oil mill effluent
description The high quantity of nutrient-rich palm oil mill effluent (POME) waste in the industry will have a severe negative environmental impact and a high cost of treatment. However, POME waste could be converted into bioenergy via environmentally sustainable processes. Several studies have explored using hydrothermal carbonisation for solid biomass products in biofuel production, but the potential of the liquid phase produced during these processes has received less attention. Therefore, this study aims to assess the potential of biohydrogen production from treated POME as a substrate by hydrothermal process. This study is presented in two phases: the first phase involves substrate pre-treatment using a hydrothermal process to improve biomass properties at different temperatures, and the second phase explores the potential for biohydrogen production from treated POME through dark fermentation. Substrate pre-treatment was conducted at 180, 210, and 240 �C using 100 % raw POME. Next, the treated POME was incubated for biohydrogen production at 50 �C for 24 h. A microbial analysis was conducted to determine the most dominant species present in the sample. Our findings show that at 180 �C, the total chemical oxygen demand (COD) removal efficiency was 80 %, and acetic acid concentration was 28 %. Compared to raw POME, treated POME generated a maximum hydrogen yield and rate (HPR) of 52.19 mL H2 g?1 CODrem and 0.59 mL H2 mL POME?1 day?1 with a 2.32-fold and 1.59-fold increase, respectively. Meanwhile, Clostridium was a dominant bacterial species identified in the treated POME. These findings demonstrated the feasibility of implementing a hydrothermal process to treat POME and improve its biohydrogen production efficiency. The treated POME from the hydrothermal process is more homogenous and readily consumable by microorganisms used in dark fermentation. Hydrothermal pre-treatment could potentially increase the rate and efficiency of microbial digestion, leading to enhanced hydrogen production. The high COD removal efficiency during the process significantly reduces the environmental impact of POME discharge, and converting POME into a valuable resource through the hydrothermal and dark fermentation process aligns with sustainable waste management practices. ? 2024 The Institution of Chemical Engineers
author2 57200914760
author_facet 57200914760
Zainal B.S.
Yu K.L.
Ong H.C.
Mohamed H.
Ker P.J.
Abdulkreem-Alsultan G.
Taufiq-Yap Y.H.
Mahlia T.I.
format Article
author Zainal B.S.
Yu K.L.
Ong H.C.
Mohamed H.
Ker P.J.
Abdulkreem-Alsultan G.
Taufiq-Yap Y.H.
Mahlia T.I.
author_sort Zainal B.S.
title Synergising hydrothermal pre-treatment and biological processes for enhancing biohydrogen production from palm oil mill effluent
title_short Synergising hydrothermal pre-treatment and biological processes for enhancing biohydrogen production from palm oil mill effluent
title_full Synergising hydrothermal pre-treatment and biological processes for enhancing biohydrogen production from palm oil mill effluent
title_fullStr Synergising hydrothermal pre-treatment and biological processes for enhancing biohydrogen production from palm oil mill effluent
title_full_unstemmed Synergising hydrothermal pre-treatment and biological processes for enhancing biohydrogen production from palm oil mill effluent
title_sort synergising hydrothermal pre-treatment and biological processes for enhancing biohydrogen production from palm oil mill effluent
publisher Institution of Chemical Engineers
publishDate 2025
_version_ 1825816138649436160
score 13.244413

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