Dynamics of copper and tetracyclines during composting of water hyacinth biomass amended with peat or pig manure

文献类型: 外文期刊

第一作者: Lu, Xin

作者: Lu, Xin;Liu, Lizhu;Fan, Ruqin;Luo, Jia;Yan, Shaohua;Zhang, Zhenhua;Rengel, Zed;Zhang, Zhenhua

作者机构:

关键词: Composting;Copper;Phytoremediation plant;Speciation availability;Tetracyclines

期刊名称:ENVIRONMENTAL SCIENCE AND POLLUTION RESEARCH ( 影响因子:4.223; 五年影响因子:4.306 )

ISSN:

年卷期:

页码:

收录情况: SCI

摘要: Composting is one of the post-treatment methods for phytoremediation plants. Due to a high potential of water hyacinth to accumulate pollutants, the physicochemical parameters, microbial activity as well as fates of copper (Cu) and tetracyclines (TCs) were investigated for the different amended water hyacinth biomass harvested from intensive livestock and poultry wastewater, including unamended water hyacinth (W), water hyacinth amended with peat (WP), and water hyacinth amended with pig manure (WPM) during the composting process. Pig manure application accelerated the composting process as evidenced by an increase of temperature, electrical conductivity (EC), NH4-N, as well as functional diversity of microbial communities compared to W and WP treatments. Composting process was slowed down by high Cu, but not by TCs. The addition of peat significantly increased the residual fraction of Cu, while pig manure addition increased available Cu concentration in the final compost. Cu could be effectively transformed into low available (oxidizable) and residual fractions after fermentation. In contrast, less than 0.5% of initial concentrations of TCs were determined at the end of 60-day composting for all treatments in the final composts. The dissipation of TCs was accelerated by the high Cu concentration during composting. Therefore, composting is an effective method for the post-treatment and resource utilization of phytoremediation plants containing Cu and/or TCs.

分类号: X5`X

  • 相关文献

[1]Effect of aeration rate, moisture content and composting period on availability of copper and lead during pig manure composting. Shen, Yujun,Zhao, Lixin,Meng, Haibo,Hou, Yueqing,Zhou, Haibin,Cheng, Hongsheng,Shen, Yujun,Zhao, Lixin,Meng, Haibo,Hou, Yueqing,Zhou, Haibin,Cheng, Hongsheng,Wang, Fei,Liu, Hongbin. 2016

[2]Interaction of veterinary antibiotic tetracyclines and copper on their fates in water and water hyacinth (Eichhornia crassipes). Lu, Xin,Gao, Yan,Luo, Jia,Yan, Shaohua,Zhang, Zhenhua,Lu, Xin,Gao, Yan,Luo, Jia,Yan, Shaohua,Zhang, Zhenhua,Rengel, Zed,Zhang, Zhenhua. 2014

[3]Simultaneous analysis of cyromazine, sulfonamides and tetracyclines in animal wastewater and soil samples by optimized LC-MS/MS. Wei, Ruicheng. 2012

[4]Determination of Tetracyclines and Their Epimers in Agricultural Soil Fertilized with Swine Manure by Ultra-High-Performance Liquid Chromatography Tandem Mass Spectrometry. Zheng Wen-li,Zhang Li-fang,Zhang Ke-yu,Wang Xiao-yang,Xue Fei-qun. 2012

[5]Survey of Tetracyclines, Sulfonamides, Sulfamethazine, and Quinolones in UHT Milk in China Market. Han Rong-wei,Yu Qun-li,Han Rong-wei,Zheng Nan,Wang Jia-qi,Zhen Yun-peng,Li Song-li,Han Rong-wei. 2013

[6]Simultaneous Determination of Fluoroquinolones, Tetracyclines and Sulfonamides in Chicken Muscle by UPLC-MS-MS. Shen, Jianzhong,Guo, Liming,Xu, Fei,Xia, Xi,Li, Xiaowei,Ding, Shuangyang,Rao, Qinxiong.

[7]SOLID SURFACE ROOM TEMPERATURE PHOSPHORESCENCE OF TETRACYCLINE ANTIBIOTICS. Xie, HZ,Dong, CA,Jin, WJ,Wei, YS,Liu, CS,Zhang, SS,Zhou, BL.

[8]Ultrasensitive chemiluminescence of tetracyclines in the presence of MCLA. Zeng, Wangsheng,Zhu, Chenyao,Liu, Jing,Cai, Hongping,Cheng, Xianglei,Wei, Lijun,Liu, Hongcheng.

[9]Antibiotics and Antibiotic Resistance Genes in Sediment of Honghu Lake and East Dongting Lake, China. Yang, Yuyi,Cao, Xinhua,Wang, Jun,Cao, Xinhua,Lin, Hui,Wang, Jun.

[10]Study on Packing Materials for High-temperature Compost of Livestock Manure. Li Ji-jin,Sun Qin-ping,Zou Guo-yuan,Xu Jun-xiang,Gao Li-juan,Luo Yi-ming. 2013

[11]Evaluation of humic substances during co-composting of sewage sludge and corn stalk under different aeration rates. Li, Shuyan,Li, Danyang,Li, Guoxue,Zhang, Bangxi,Li, Jijin,Zhang, Bangxi.

[12]Gentamicin degradation and changes in fungal diversity and physicochemical properties during composting of gentamicin production residue. Liu, Yuanwang,Feng, Yao,Cheng, Dengmiao,Hu, Haiyan,Li, Zhaojun,Xue, Jianming,Xue, Jianming,Wakelin, Steve A..

[13]Rapid estimation of nutrients in chicken manure during plant-field composting using physicochemical properties. Huang, Guangqun,Han, Lujia,Wang, Xiaoyan.

[14]Various sulphur fractions changes during different manure composting. Bao, Yanyu,Zhou, Qixing,Guan, Lianzhu,Yan, Li,Wang, He.

[15]Control of Nitrogen Loss during Co-Composting of Banana Stems with Chicken Manure. Wu, Chunyuan,Li, Qinfen,Zhang, Yubai. 2011

[16]Odorous composting gas abatement and microbial community diversity in a biotrickling filter. Xue, Niantao,Wang, Qunhui,Wang, Juan,Wang, Jianhua,Xue, Niantao,Wang, Qunhui,Sun, Xiaohong.

[17]Straw biochar hastens organic matter degradation and produces nutrient-rich compost. Zhang, Jining,Chen, Guifa,Sun, Huifeng,Zhou, Sheng,Zou, Guoyan,Zhang, Jining,Chen, Guifa,Sun, Huifeng,Zhou, Sheng,Zou, Guoyan,Zou, Guoyan.

[18]Influence of bulking agents on CH4, N2O, and NH3 emissions during rapid composting of pig manure from the Chinese Ganqinfen system. Sun, Xiang-ping,Sun, Xiang-ping,Li, Guo-xue,Lu, Peng,Jiang, Tao,Schuchardt, Frank. 2014

[19]Bacterial and fungal communities and contribution of physicochemical factors during cattle farm waste composting. Huhe,Huhe,Huhe,Jiang, Chao,Wu, Yanpei,Cheng, Yunxiang. 2017

[20]AMMONIA AND GREENHOUSE GAS EMISSIONS FROM CO-COMPOSTING OF DEAD HENS WITH MANURE AS AFFECTED BY FORCED AERATION RATE. Zhu, Z.,Dong, H.,Xi, J.,Xin, H..

作者其他论文 更多>>

微信小程序