Sage Journals: Discover world-class research

Abstract

Methane (CH₄) emissions from sewage sludge composting can be reduced by using biochar more effectively. This study investigates the impact of different structure of biochar on CH₄ emissions during sewage sludge composting. Corncob biochar (CB, pore size = 35.3990 nm), rice husk biochar (RB, pore size = 3.4242 nm) and wood biochar (WB, pore size = 1.6691 nm) were applied to the composting. The results showed that biochar decreased CH₄ emissions, mainly through the indirect effect of improving the pile environment. Compared with the control group (CK), the biochars with smaller pore structures, WB and RB, reduced CH₄ emissions by 41.83% and 33.59%, respectively, compared to only 8.20% for CB, which has a larger pore structure. In addition, RB and WB increased the free air space (FAS) by more than 10% and CB improved the microbial diversity. Methanothermobacter was reported in WB and RB, with an abundance of 45.45% in WB. Redundancy analysis (RDA) showed that pore size was positively correlated with the CH₄ emission rate. The results of this study can provide a theoretical reference for CH₄ reduction from biochar co-composting of sewage sludge.

Keywords

Biochar sewage sludge composting methane pore structure microbial

Get full access to this article

View all access options for this article.

References

Agnew

Leonard

(2003) The physical properties of compost. Compost Science & Utilization 11: 238–264.

Atkinson

Fitzgerald

Hipps

(2010) Potential mechanisms for achieving agricultural benefits from biochar application to temperate soils: A review. Plant & Soil 337: 1–18.

Awasthi

Wang

Chen

, et al. (2017) Heterogeneity of biochar amendment to improve the carbon and nitrogen sequestration through reduce the greenhouse gases emissions during sewage sludge composting. Bioresource Technology 224: 428–438.

Chen

Wang

Wei

, et al. (2014) Windrow composting mitigated CH4 emissions: Characterization of methanogenic and methanotrophic communities in manure management. FEMS Microbiology Ecology 90: 575–586.

Chen

Liao

, et al. (2017) Effects of different types of biochar on methane and ammonia mitigation during layer manure composting. Waste Management 61: 506–515.

Duan

Yang

Guo

, et al. (2021) Pollution control in biochar-driven clean composting: Emphasize on heavy metal passivation and gaseous emissions mitigation. Journal of Hazardous Materials 420: 126635.

Gan

Cheng

Jin

, et al. (2021) Hierarchical porous biochar from plant-based biomass through selectively removing lignin carbon from biochar for enhanced removal of toluene. Chemosphere 279: 130514.

Godlewska

Schmidt

, et al. (2017) Biochar for composting improvement and contaminants reduction: A review. Bioresource Technology 246: 193–202.

Guo

Wang

, et al. (2021a) Microbial mechanisms related to the effects of bamboo charcoal and bamboo vinegar on the degradation of organic matter and methane emissions during composting. Environmental Pollution 272: 116013.

10.

Guo

X-X

S-B

Wang

X-Q

, et al. (2021b) Impact of biochar addition on three-dimensional structural changes in aggregates associated with humus during swine manure composting. Journal of Cleaner Production 280: 124380.

11.

Hoang

Bolan

Madhubashani

AMP

, et al. (2022) Treatment processes to eliminate potential environmental hazards and restore agronomic value of sewage sludge: A review. Environmental Pollution 293: 118564.

12.

Jung

Chen

, et al. (2021) Biochar industry to circular economy. Science of The Total Environment 757: 143820.

13.

Azeez

(2019) Green entrepreneurship: Literature review and agenda for future research. International Journal of Entrepreneurial Knowledge 7: 17–29.

14.

Jandačka

Mičieta

Holubčík

, et al. (2017) Experimental determination of bed temperatures during wood pellet combustion. Energy & Fuels 31: 2919–2926.

15.

Hettiaratchi

JPA

Achari

(2019) The influence of biochar and compost mixtures, water content, and gas flow rate, on the continuous adsorption of methane in a fixed bed column. Journal of Environmental Management 233: 175–183.

16.

Leng

Xiong

Yang

, et al. (2021) An overview on engineering the surface area and porosity of biochar. Science of The Total Environment 763: 144204.

17.

Lenhard

Malcho

Jandačka

(2019) Modelling of heat transfer in the evaporator and condenser of the working fluid in the heat pipe. Heat Transfer Engineering 40: 215–226.

18.

Liu

Zheng

Chen

, et al. (2014) Reduction in greenhouse gas emissions from sewage sludge aerobic compost in China. Water Science and Technology 69(6): 1129–1135.

19.

Liu

Zhou

Han

, et al. (2017) Role and multi-scale characterization of bamboo biochar during poultry manure aerobic composting. Bioresource Technology 241: 190–199.

20.

Lü

Chen

X-H

C-H

, et al. (2021) Occurrence and dissipation mechanism of organic pollutants during the composting of sewage sludge: A critical review. Bioresource Technology 328: 124847.

21.

Ming

, et al. (2020) Performance evaluation in composting of sewage sludge with different bulking agents. Journal of Environmental Engineering 146: 05020002.

22.

Mardoyan

Braun

(2015) Analysis of Czech subsidies for solid biofuels. International Journal of Green Energy 12: 405–408.

23.

Maroušek

Gavurová

(2022) Recovering phosphorous from biogas fermentation residues indicates promising economic results. Chemosphere 291: 133008.

24.

Maroušek

Trakal

(2022) Techno-economic analysis reveals the untapped potential of wood biochar. Chemosphere 291: 133000.

25.

Michalska

Turek-Szytow

Dudło

, et al. (2022) Characterization of humic substances recovered from the sewage sludge and validity of their removal from this waste. EFB Bioeconomy Journal 2: 100026.

26.

Qambrani

Rahman

Won

, et al. (2017) Biochar properties and eco-friendly applications for climate change mitigation, waste management, and wastewater treatment: A review. Renewable and Sustainable Energy Reviews 79: 255–273.

27.

Rogger

Beaurain

Schmidt

(2011) Composting projects under the clean development mechanism: Sustainable contribution to mitigate climate change. Waste Management 31(1): 138–146.

28.

Soares

MAR

Quina

Quinta-Ferreira

(2013) Prediction of free air space in initial composting mixtures by a statistical design approach. Journal of Environmental Management 128: 75–82.

29.

Sowers

(2019) Methanogenesis✩. In: Schmidt

(ed.) Encyclopedia of Microbiology, 4th edn. Oxford: Academic Press, pp.53–73.

30.

Stávková

Maroušek

(2021) Novel sorbent shows promising financial results on P recovery from sludge water. Chemosphere 276: 130097.

31.

Subirats

Sharpe

Topp

(2022) Fate of Clostridia and other spore-forming Firmicute bacteria during feedstock anaerobic digestion and aerobic composting. Journal of Environmental Management 309: 114643.

32.

Wei

Shutao

Jin

, et al. (2014) Biochar influences the microbial community structure during tomato stalk composting with chicken manure. Bioresource Technology 154: 148–154.

33.

Xiao

Awasthi

, et al. (2017) Recent developments in biochar utilization as an additive in organic solid waste composting: A review. Bioresource Technology 246: 203–213.

34.

Yang

Shi

, et al. (2015) Effects of phosphogypsum and superphosphate on compost maturity and gaseous emissions during kitchen waste composting. Waste Management 36: 70–76.

35.

Yin

Yang

, et al. (2021) Research progress and prospects for using biochar to mitigate greenhouse gas emissions during composting: A review. Science of The Total Environment 798: 149294.

36.

Grant Clark

Leonard

(2009) Influence of free air space on microbial kinetics in passively aerated compost. Bioresource Technology 100(2): 782–790.

37.

Zhang

, et al. (2021) Downward aeration promotes static composting by affecting mineralization and humification. Bioresource Technology 338: 125592.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

3.23 MB

Impact of different structures of biochar on decreasing methane emissions from sewage sludge composting

Abstract

Keywords

Get full access to this article

References

Supplementary Material