Reducing greenhouse gas emissions and enhancing carbon and nitrogen conversion in food wastes by the black soldier fly

Currently, sustainable utilisation, including recycling and valorisation, is becoming increasingly relevant in environmental management. The wastes bioconversion by the black soldier fly larva (BSFL) has two potential advantages: the larvae can convert the carbon and nitrogen in the biomass waste, a...

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Bibliographic Details
Published in:Journal of environmental management 2020-04, Vol.260, p.110066-110066, Article 110066
Main Authors: Pang, Wancheng, Hou, Dejia, Chen, Jiangshan, Nowar, Elhosseny E., Li, Zongtian, Hu, Ronggui, Tomberlin, Jeffery K., Yu, Ziniu, Li, Qing, Wang, Shucai
Format: Article
Language:English
Subjects:
Animals
Black soldier fly
Carbon
Carbon and nitrogen conversion
Carbon Dioxide
Food
Food waste
Greenhouse gas
Greenhouse Gases
Methane
Nitrogen
pH values
Refuse Disposal
Simuliidae
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Summary:Currently, sustainable utilisation, including recycling and valorisation, is becoming increasingly relevant in environmental management. The wastes bioconversion by the black soldier fly larva (BSFL) has two potential advantages: the larvae can convert the carbon and nitrogen in the biomass waste, and improve the properties of the substrate to reduce the loss of gaseous carbon and nitrogen. In the present study, the conversion rate of carbon, nitrogen and the emissions of greenhouse gases and NH3 during BSFL bio-treatment of food waste were investigated under different pH conditions. The results showed that the pH of the raw materials is a pivotal parameter affecting the process. The average wet weight of harvested BSFL was 13.26–95.28 mg/larva, with about 1.95–13.41% and 5.40–18.93% of recycled carbon and nitrogen from substrate at a pH from 3.0 to 11.0, respectively. Furthermore, pH is adversely correlated with CO2 emissions, but positively with NH3 emissions. Cumulative CO2, NH3, CH4 and N2O emissions at pH ranging from 3.0 to 11.0 were 88.15–161.11 g kg−1, 0.15–1.68 g kg−1, 0.19–2.62 mg kg−1 and 0.02–1.65 mg kg−1, respectively. Compared with the values in open composting, BSFL bio-treatment of food waste could lead greenhouse gas (especially CH4 and N2O) and NH3 emissions to decrease. Therefore, a higher pH value of the substrate can increase the larval output and help the mitigation of greenhouse gas emissions. [Display omitted] •Greenhouse gas and NH3 emissions were measured for black soldier fly (BSF) treatment.•BSF recycled 1.95–13.41% of C and 5.40–18.93% of N from food waste into biomass.•BSF bio-conversion of food waste greatly decreased CH4 and N2O emissions.•Increasing initial pH value of the substrate promoted larval growth.
ISSN:0301-4797
1095-8630
DOI:10.1016/j.jenvman.2020.110066