Effects of biochar size and type on gaseous emissions during pig manure/wheat straw aerobic composting: Insights into multivariate-microscale characterization and microbial mechanism

[Display omitted] •Granular-biochar improved pore volume and was benefit to methanotrophs activities.•Higher aromatic compounds on surface of bamboo biochar and NO3− formed π–π EDA.•Rice straw biochar is rich in reactive functional groups to adsorb NH4+.•Powder bamboo biochar was most suitable for c...

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Veröffentlicht in:	Bioresource technology 2019-01, Vol.271 (C), p.375-382
Hauptverfasser:	He, Xueqin, Yin, Hongjie, Han, Lujia, Cui, Ruxiu, Fang, Chen, Huang, Guangqun
Format:	Artikel
Sprache:	eng
Schlagworte:	Aerobiosis Ammonia Ammonia - analysis Animals Biochar Charcoal - chemistry Charcoal - metabolism Composting - instrumentation Denitrification Gases - chemistry Gases - metabolism Greenhouse gas Manure Microbial mechanism Oryza - chemistry Oryza - metabolism Particle size Swine Triticum - metabolism
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container_title	Bioresource technology
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creator	He, Xueqin Yin, Hongjie Han, Lujia Cui, Ruxiu Fang, Chen Huang, Guangqun
description	[Display omitted] •Granular-biochar improved pore volume and was benefit to methanotrophs activities.•Higher aromatic compounds on surface of bamboo biochar and NO3− formed π–π EDA.•Rice straw biochar is rich in reactive functional groups to adsorb NH4+.•Powder bamboo biochar was most suitable for controlling GHG and ammonia emissions. Greenhouse gas and ammonia emissions during composting with different biochar types and particle sizes were investigated. Compared with powder-biochar, granular-biochar improved pore connectivity and was benefit to methanotrophs activities, like Methylococcaceae, reducing CH4 emissions. At the same particle size, bamboo biochar (BB) had a higher pore volume and more aerobic microenvironment within the compost than rice straw biochar (RSB), reducing GHG emissions. Bamboo biochar had high aromatic compound and NO3− concentrations and therefore surface π–π electron donor/acceptor interactions, causing low N2O emissions and inhibiting denitrifying bacteria (e.g., Bacteroidales). More CO and CO bonds in rice straw biochar than bamboo biochar caused lower NH3 emissions using rice straw than bamboo biochar. Powdered biochar had more exposed reactive functional groups and decreased NH3 production better than granular biochar. Powdered bamboo biochar controls gaseous emissions better than other biochars during aerobic pig manure/wheat straw composting.
doi_str_mv	10.1016/j.biortech.2018.09.104
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Greenhouse gas and ammonia emissions during composting with different biochar types and particle sizes were investigated. Compared with powder-biochar, granular-biochar improved pore connectivity and was benefit to methanotrophs activities, like Methylococcaceae, reducing CH4 emissions. At the same particle size, bamboo biochar (BB) had a higher pore volume and more aerobic microenvironment within the compost than rice straw biochar (RSB), reducing GHG emissions. Bamboo biochar had high aromatic compound and NO3− concentrations and therefore surface π–π electron donor/acceptor interactions, causing low N2O emissions and inhibiting denitrifying bacteria (e.g., Bacteroidales). More CO and CO bonds in rice straw biochar than bamboo biochar caused lower NH3 emissions using rice straw than bamboo biochar. Powdered biochar had more exposed reactive functional groups and decreased NH3 production better than granular biochar. 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Greenhouse gas and ammonia emissions during composting with different biochar types and particle sizes were investigated. Compared with powder-biochar, granular-biochar improved pore connectivity and was benefit to methanotrophs activities, like Methylococcaceae, reducing CH4 emissions. At the same particle size, bamboo biochar (BB) had a higher pore volume and more aerobic microenvironment within the compost than rice straw biochar (RSB), reducing GHG emissions. Bamboo biochar had high aromatic compound and NO3− concentrations and therefore surface π–π electron donor/acceptor interactions, causing low N2O emissions and inhibiting denitrifying bacteria (e.g., Bacteroidales). More CO and CO bonds in rice straw biochar than bamboo biochar caused lower NH3 emissions using rice straw than bamboo biochar. Powdered biochar had more exposed reactive functional groups and decreased NH3 production better than granular biochar. 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subjects	Aerobiosis Ammonia Ammonia - analysis Animals Biochar Charcoal - chemistry Charcoal - metabolism Composting - instrumentation Denitrification Gases - chemistry Gases - metabolism Greenhouse gas Manure Microbial mechanism Oryza - chemistry Oryza - metabolism Particle size Swine Triticum - metabolism
title	Effects of biochar size and type on gaseous emissions during pig manure/wheat straw aerobic composting: Insights into multivariate-microscale characterization and microbial mechanism
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