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Potential Mineralization of Various Organic Pollutants During Composting 被引量:1

Potential Mineralization of Various Organic Pollutants During Composting
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摘要 The objectives of this work were to determine the potential mineralization of various organic pollutants that are likely found in compostable materials during composting, and to evaluate the participation of the microflora of the thermophilic and maturation composting phases in pollutant mineralization. Four composts were used: a biowaste compost (BioW), a municipal solid waste compost (MSW), a green waste compost (GW) and a co-compost of green waste and sludge (GW+S). In each composting plant, two samples were withdrawn: one in the thermophilic phase (fresh compost) and one in the maturation phase (mature compost) to have the microflora of thermophilic and maturation phases active, respectively. The mineralization of 5 organic pollutants, 3 polycyclic aromatic hydrocarbons (PAHs) (i.e., phenanthrene, fluoranthene and benzo(a)pyrene), 1 herbicide (dicamba) and 1 polychlorinated biphenyl (PCB, congener 52), was measured in a laboratory setting during incubations at 60 ~C in fresh composts and at 28 ~C in mature composts. All molecules were 14C-labeled, which allowed the mineralization of the molecules to be measured by trapping of produced 14CO2 in NaOH. Their volatilization was also measured by trapping molecules on glass wool impregnated with paraffin oil. Mineralization of the organic molecules was only observed when the maturation microflora was present in the mature composts or when it was inoculated into the fresh compost. Phenanthrene mineralization of up to 60% in the fresh GW^S compost was the only exception. Mineralization of PAH decreased when the complexity of the PAH molecules increased. Mineralization of phenanthrene and fluoranthene reached 50%-70% in all mature composts. Benzo(a)pyrene was mineralized (30%) only in the MSW mature compost. Dicamba was moderately mineralized (30%-40%). Finally, no PCB mineralization was detected, but 20% of the PCB had volatilized after 12 d at 60 ℃. No clear difference was observed in the degrading capacity of the different composts, and the major difference was the larger mineralizing capacity of the maturation microflora compared with the thermophilic microflora. The objectives of this work were to determine the potential mineralization of various organic pollutants that are likely found in compostable materials during composting, and to evaluate the participation of the microflora of the thermophilic and maturation composting phases in pollutant mineralization. Four composts were used: a biowaste compost (BioW), a municipal solid waste compost (MSW), a green waste compost (GW) and a co-compost of green waste and sludge (GW+S). In each composting plant, two samples were withdrawn: one in the thermophilic phase (fresh compost) and one in the maturation phase (mature compost) to have the microflora of thermophilic and maturation phases active, respectively. The mineralization of 5 organic pollutants, 3 polycyclic aromatic hydrocarbons (PAHs) (i.e., phenanthrene, fluoranthene and benzo(a)pyrene), 1 herbicide (dicamba) and 1 polychlorinated biphenyl (PCB, congener 52), was measured in a laboratory setting during incubations at 60 ℃ in fresh composts and at 28 ℃ in mature composts. All molecules were 14 C-labeled, which allowed the mineralization of the molecules to be measured by trapping of produced 14CO2 in NaOH. Their volatilization was also measured by trapping molecules on glass wool impregnated with paraffin oil. Mineralization of the organic molecules was only observed when the maturation microflora was present in the mature composts or when it was inoculated into the fresh compost. Phenanthrene mineralization of up to 60% in the fresh GW+S compost was the only exception. Mineralization of PAH decreased when the complexity of the PAH molecules increased. Mineralization of phenanthrene and fluoranthene reached 50%-70% in all mature composts. Benzo(a)pyrene was mineralized (30%) only in the MSW mature compost. Dicamba was moderately mineralized (30%-40%). Finally, no PCB mineralization was detected, but 20% of the PCB had volatilized after 12 d at 60 ℃. No clear difference was observed in the degrading capacity of the different composts, and the major difference was the larger mineralizing capacity of the maturation microflora compared with the thermophilic microflora.
出处 《Pedosphere》 SCIE CAS CSCD 2012年第4期536-543,共8页 土壤圈(英文版)
基金 Supported by the Veolia Group,France,and the INRA,France
关键词 COMPOST DICAMBA MATURITY PAH PCB 有机污染物 堆肥过程 矿化 苯并(a)芘 成熟阶段 城市固体废弃物 生物污染物 嗜热微生物
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  • 1Alcock, R E. and Jones, K. C. 1993. Polychlorinated biphenyls in digested UK sewage sludges. Chemosphere. 26: 2199-2207.
  • 2Andelman, J. B. and Suess, M. J. 1970. Polynuclear aromatic hydrocarbons in the water environment. B. World Health Organ. 43: 479-508.
  • 3Barriuso, E., Calvet, R., Schiavon, M. and Soulas, G. 1996. Les pesticides et les polluants organiques des sols. Transforma?tions et dissipation. Etude et Gestion des Sols (in French). 3: 279-296.
  • 4Barriuso, E., Benoit, P. and Dubus, I. G. 2008. Formation of pes?ticide nonextractable (bound) residues in soil: Magnitude, controlling factors and reversibility. Environ. Sci. Technol. 42: 1845-1854.
  • 5Bourdin, J. and Andre, L. 1975. Residus de dicamba dans les terreaux confectionnes a. partir de coupes de gazon traites. Phytiatrie-Phytopharmacie (in French). 24: 297-304.
  • 6Brandli, R C., Bucheli, T. D., Kupper, T., Furrer, R, Stadel?mann, F. X. and Tarradellas, J. 2005. Persistent organic pollutants in source-separated compost and its feedstock materials: A review of field studies. J. Environ. Qual. 34: 735-760.
  • 7Brandli, R. C., Bucheli, T. D., Kupper, T., Mayer, J., Stadel?mann, F. X. and Tarradellas, J. 2007. Fate of PCBs, PAHs and their source characteristic ratios during composting and digestion of source-separated organic waste in full-scale plants. Environ. Pollut. 148: 520-528.
  • 8Biiyiiks6nmez, F., Rynk, R., Hess, T. F. and Bechinski, E. 1999. Occurrence, degradation and fate of pesticides during com?posting. Part I: composting, pesticides and pesticide degra?dation. Compost Sci. Util. 7: 66-82.
  • 9Biiyuksonmez, F., Rynk, R., Hess, T. F. and Bechinski, E. 2000. Occurrence, degradation and fate of pesticides during com?posting. Part II: Occurrence and fate of pesticides in com?post and composting systems. Compost Sci. Util. 8: 61-81.
  • 10Cerniglia, C. E. 1992. Biodegradation of polycyclic aromatic hydrocarbons. Biodegrodation. 3: 351-368.

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