Effect of biochar addition on the removal of organic and nitrogen pollutants from leachate treated with a semi-aerobic aged refuse biofilter

Abstract

The effect of biochar on the removal of organic and nitrogen contaminants from leachate in a semi-aerobic aged refuse biofilter (SAARB) was investigated. A preset amount of biochar was mixed with the aged refuse to explore the enhancement ability of pollutant removal by characterizing the leachate effluent and gas. The results showed that biochar contributed to the removal of organic and nitrogen pollutants from the leachate and that increasing the amount of biochar added led to higher colour number, chemical oxygen demand, ammonia nitrogen, and total nitrogen removal efficiencies. Furthermore, the addition of biochar significantly increased the removal of large molecule organic pollutants from the leachate. The improved removal of organics was due to the considerable number of surface functional groups and the large surface area of the biochar, which effectively absorbed and removed a significant amount of the organic matter from the leachate. Biochar elevated the dissolved oxygen concentration in the semi-aerobic system, which facilitated the completion of the nitrification reaction. It also promoted denitrification by acting as a supplementary carbon source. The nitrous oxide (N₂O) emissions decreased as the amount of biochar added increased. When the biochar proportion reached 3%, the N₂O emission was only 1.11% of the original total nitrogen and the di-nitrogen emission was 19.61%. The findings of this study can be used to improve the treatment of leachate using biochar combined with a SAARB.

Keywords

Semi-aerobic aged refuse biofilter biochar landfill leachate organic and nitrogen pollutants

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References

Aktaş

Çeçen

(2007) Bioregeneration of activated carbon: A review. International Biodeterioration & Biodegradation 59: 257–272.

Baker

Curry

(2004) Fluorescence of leachates from three contrasting landfills. Water Research 38: 2605–2613.

Beheydt

Boeckx

Ahmed

, et al. (2008) N₂O emission from conventional and minimum-tilled soils. Biology and Fertility of Soils 44: 863–873.

Chedly

Latifa

Loubna

, et al. (2007) Landfill leachate treatment with ozone and ozone/hydrogen peroxide systems. Journal of Hazardous Materials 140: 316–324.

Chen

Zhu

Bañuelos

, et al. (2020) Biochar reduces nitrous oxide but increases methane emissions in batch wetland mesocosms. Chemical Engineering Journal 392: 124842.

Cornard

J-P

Caudron

Merlin

J-C

(2006) UV–visible and synchronous fluorescence spectroscopic investigations of the complexation of Al(III) with caffeic acid, in aqueous low acidic medium. Polyhedron 25: 2215–2222.

Guanghuan

Jianqiang

Xiaoling

, et al. (2017) Effects of influent COD/N ratios on nitrous oxide emission in a sequencing biofilm batch reactor for simultaneous nitrogen and phosphorus removal. Scientific Reports 7: 1–9.

Hale

Alling

Martinsen

, et al. (2013) The sorption and desorption of phosphate-P, ammonium-N and nitrate-N in cacao shell and corn cob biochars. Chemosphere 91: 1612–1619.

Han

Liu

(2013) A removal mechanism for organics and nitrogen in treating leachate using a semi-aerobic aged refuse biofilter. Journal of Environmental Management 114: 336–342.

10.

Han

Liu

, et al. (2011) A novel technique of semi-aerobic aged refuse biofilter for leachate treatment. Waste Management 31: 1827–1832.

11.

Liu

Zhang

, et al. (2007) Characteristics of the bioreactor landfill system using an anaerobic-aerobic process for nitrogen removal. Bioresource Technology 98: 2526–2532.

12.

Kjeldsen

Barlaz

Rooker

, et al. (2002) Present and long-term composition of MSW landfill leachate: A review. Critical Reviews in Environmental Science and Technology 32: 297–336.

13.

Kong

Xiong

Sun

, et al. (2014) Sorption performance and mechanism of a sludge-derived char as porous carbon-based hybrid adsorbent for benzene derivatives in aqueous solution. Journal of Hazardous Materials 274: 205–211.

14.

Lei

Chengyao

Yongzhen

, et al. (2012) Effect of wastewater COD/N ratio on aerobic nitrifying sludge granulation and microbial population shift. Journal of Environmental Sciences 24: 234–241.

15.

Liu

J-J

Diao

Z-H

Liu

C-M

, et al. (2018) Synergistic reduction of copper (II) and oxidation of norfloxacin over a novel sewage sludge-derived char-based catalyst: Performance, fate and mechanism. Journal of Cleaner Production 182: 794–804.

16.

Miao

Yang

Tao

, et al. (2019) Recent advances in nitrogen removal from landfill leachate using biological treatments: A review. Journal of Environmental Management 235: 178–185.

17.

Pascal

Joachim

Adriano

, et al. (2012) Mechanisms of N₂O production in biological wastewater treatment under nitrifying and denitrifying conditions. Water Research 46: 1027–1037.

18.

Tizaoui

Bouselmi

Mansouri

, et al. (2007) Landfill leachate treatment with ozone and ozone/hydrogen peroxide systems. Journal of Hazardous Materials 140: 316–324.

19.

Troy

Lawlor

Flynn

, et al. (2013) Impact of biochar addition to soil on greenhouse gas emissions following pig manure application. Soil Biology and Biochemistry 60: 173–181.

20.

Wang

(2019) Preparation, modification and environmental application of biochar: A review. Journal of Cleaner Production 227: 1002–1022.

21.

Xiao-Song

Bei-Dou

Ru-Tai

, et al. (2016) Insight into the composition and degradation potential of dissolved organic matter with different hydrophobicity in landfill leachates. Chemosphere 144: 75–80.

22.

Chenglong

Lixia

, et al. (2018) An innovative biochar-amended substrate vertical flow constructed wetland for low C/N wastewater treatment: Impact of influent strengths. Bioresource Technology 247: 844–850.

23.

Yan

Dan

Youcai

, et al. (2017) Assessment and analysis of aged refuse as ammonium-removal media for the treatment of landfill leachate. Waste Management & Research 35: 1168–1174.

24.

Yingyu

Bing-Jie

Paul

, et al. (2012) N₂O production rate of an enriched ammonia-oxidising bacteria culture exponentially correlates to its ammonia oxidation rate. Water Research 46: 3409–3419.

25.

Zhang

Huang

, et al. (2020) Spectroscopic and molecular characterization of biochar-derived dissolved organic matter and the associations with soil microbial responses. Science of the Total Environment 708: 134619.

26.

Zhen

Jian

Shanping

, et al. (2013) Impact of carbon source on nitrous oxide emission from anoxic/oxic biological nitrogen removal process and identification of its emission sources. Environmental Science and Pollution Research International 20: 1059–1069.

27.

Zhou

Wang

Zhang

, et al. (2017) Enhanced nitrogen removal of low C/N domestic wastewater using a biochar-amended aerated vertical flow constructed wetland. Bioresource Technology 241: 269–275.

28.

Zhu

(2014) Summertime N₂O, CH₄ and CO₂ exchanges from a tundra marsh and an upland tundra in maritime Antarctica. Atmospheric Environment 83: 269–281.

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