Effect of increasing salinity on biogas production in waste landfills with leachate recirculation: A lab-scale model study

Effect of increasing salinity on biogas production in waste landfills with leachate recirculation: A lab-scale model study

The effects of salinity on anaerobic waste degradation and microbial communities were investigated, in order to propose an appropriate leachate recirculation process in a waste landfill in a tropical region. A salt concentration of 21 mS cm−1 of electrical conductivity (EC) did not affect waste degr...

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Bibliographic Details
Main Authors: Yuka Ogata, Tomonori Ishigaki, Mikako Nakagawa, Masato Yamada
Format: Article
Language:English
Published: Elsevier 2016-06-01
Series:Biotechnology Reports
Subjects:
Leachate recirculation
Waste landfill
Salt accumulation
Biogas production
Microbial communities
Online Access:http://www.sciencedirect.com/science/article/pii/S2215017X16300194
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spelling doaj-2865ed07dc144fbc9abb95074023aff92020-11-25T00:55:50ZengElsevierBiotechnology Reports2215-017X2016-06-0110C11111610.1016/j.btre.2016.04.004Effect of increasing salinity on biogas production in waste landfills with leachate recirculation: A lab-scale model studyYuka OgataTomonori IshigakiMikako NakagawaMasato YamadaThe effects of salinity on anaerobic waste degradation and microbial communities were investigated, in order to propose an appropriate leachate recirculation process in a waste landfill in a tropical region. A salt concentration of 21 mS cm−1 of electrical conductivity (EC) did not affect waste degradation, but a salt concentration of 35 mS cm−1 of EC inhibited CH4 generation. A higher salt concentration of 80 mS cm−1 of EC inhibited not only CH4 and CO2 generation, but also degradation of organic compounds. The bacterial and archaeal community compositions were affected by high salinity. High salinity can exert selective pressure on bacterial communities, resulting in a change in bacterial community structure. Ammonium caused strong, dominant inhibition of biogas production in the salt concentration range of this study. Quality control, especially of ammonium levels, will be essential for the promotion of waste biodegradation in landfills with leachate recirculation.http://www.sciencedirect.com/science/article/pii/S2215017X16300194Leachate recirculationWaste landfillSalt accumulationBiogas productionMicrobial communities
collection DOAJ
language English
format Article
sources DOAJ
author Yuka Ogata
Tomonori Ishigaki
Mikako Nakagawa
Masato Yamada
spellingShingle Yuka Ogata
Tomonori Ishigaki
Mikako Nakagawa
Masato Yamada
Effect of increasing salinity on biogas production in waste landfills with leachate recirculation: A lab-scale model study
Biotechnology Reports
Leachate recirculation
Waste landfill
Salt accumulation
Biogas production
Microbial communities
author_facet Yuka Ogata
Tomonori Ishigaki
Mikako Nakagawa
Masato Yamada
author_sort Yuka Ogata
title Effect of increasing salinity on biogas production in waste landfills with leachate recirculation: A lab-scale model study
title_short Effect of increasing salinity on biogas production in waste landfills with leachate recirculation: A lab-scale model study
title_full Effect of increasing salinity on biogas production in waste landfills with leachate recirculation: A lab-scale model study
title_fullStr Effect of increasing salinity on biogas production in waste landfills with leachate recirculation: A lab-scale model study
title_full_unstemmed Effect of increasing salinity on biogas production in waste landfills with leachate recirculation: A lab-scale model study
title_sort effect of increasing salinity on biogas production in waste landfills with leachate recirculation: a lab-scale model study
publisher Elsevier
series Biotechnology Reports
issn 2215-017X
publishDate 2016-06-01
description The effects of salinity on anaerobic waste degradation and microbial communities were investigated, in order to propose an appropriate leachate recirculation process in a waste landfill in a tropical region. A salt concentration of 21 mS cm−1 of electrical conductivity (EC) did not affect waste degradation, but a salt concentration of 35 mS cm−1 of EC inhibited CH4 generation. A higher salt concentration of 80 mS cm−1 of EC inhibited not only CH4 and CO2 generation, but also degradation of organic compounds. The bacterial and archaeal community compositions were affected by high salinity. High salinity can exert selective pressure on bacterial communities, resulting in a change in bacterial community structure. Ammonium caused strong, dominant inhibition of biogas production in the salt concentration range of this study. Quality control, especially of ammonium levels, will be essential for the promotion of waste biodegradation in landfills with leachate recirculation.
topic Leachate recirculation
Waste landfill
Salt accumulation
Biogas production
Microbial communities
url http://www.sciencedirect.com/science/article/pii/S2215017X16300194
work_keys_str_mv AT yukaogata effectofincreasingsalinityonbiogasproductioninwastelandfillswithleachaterecirculationalabscalemodelstudy
AT tomonoriishigaki effectofincreasingsalinityonbiogasproductioninwastelandfillswithleachaterecirculationalabscalemodelstudy
AT mikakonakagawa effectofincreasingsalinityonbiogasproductioninwastelandfillswithleachaterecirculationalabscalemodelstudy
AT masatoyamada effectofincreasingsalinityonbiogasproductioninwastelandfillswithleachaterecirculationalabscalemodelstudy
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