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CAO Feishu, CHEN Jianping, XIE Dongyan, YAN Depeng, LIAO Changjun, SONG Hainong, ZHU Hongxiang, CHEN Guanyi. APPLICATION OF SLURRY BIOREACTOR IN SOIL REMEDIATION[J]. ENVIRONMENTAL ENGINEERING , 2022, 40(4): 174-181,201. doi: 10.13205/j.hjgc.202204025
Citation: CAO Feishu, CHEN Jianping, XIE Dongyan, YAN Depeng, LIAO Changjun, SONG Hainong, ZHU Hongxiang, CHEN Guanyi. APPLICATION OF SLURRY BIOREACTOR IN SOIL REMEDIATION[J]. ENVIRONMENTAL ENGINEERING , 2022, 40(4): 174-181,201. doi: 10.13205/j.hjgc.202204025

APPLICATION OF SLURRY BIOREACTOR IN SOIL REMEDIATION

doi: 10.13205/j.hjgc.202204025
  • Received Date: 2021-09-22
    Available Online: 2022-07-06
  • Slurry bioreactor can be applied in the remediation of high-concentration contaminated soils, and resist harsh condition by implementing oxygen and nutrients. It also shows advantages in high treatment efficiency and easy control of bioremediation process. This study introduced the removal ratios of non-biodegradable organics, i.e., polycyclic aromatic hydrocarbons (PAHs), polychlorinated biphenyls (PCBs), pentachlorophenol (PCP) and total petroleum hydrocarbons (TPH), by the slurry bioreactor. The effects of pollutants characteristics, biodegradation pathways, water-soil ratio and operational parameters (such as pH, temperature, dissolved oxygen, etc.) in the contaminants’ removal process were compared. The related techniques, engineering cases and application costs of slurry bioreactors were also reviewed. Due to its relevant high cost and complex biodegradation mechanisms, slurry bioreactor was mainly studied in the laboratory nowadays in China. As a promising bioremediation technology, it is necessary to further improve the treatment efficiency of slurry bioreactor and reduce the application cost in the future to promote the application.
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    Created with Highcharts 5.0.7Chart context menuAccess Area Distribution其他: 17.3 %其他: 17.3 %其他: 2.2 %其他: 2.2 %Grove City: 0.3 %Grove City: 0.3 %Norman: 0.3 %Norman: 0.3 %Valencia: 0.3 %Valencia: 0.3 %[]: 0.3 %[]: 0.3 %上海: 1.6 %上海: 1.6 %东莞: 0.3 %东莞: 0.3 %临汾: 0.3 %临汾: 0.3 %临沂: 0.3 %临沂: 0.3 %佩森: 0.3 %佩森: 0.3 %保定: 0.3 %保定: 0.3 %北京: 4.5 %北京: 4.5 %十堰: 0.6 %十堰: 0.6 %南京: 1.3 %南京: 1.3 %南宁: 0.3 %南宁: 0.3 %南昌: 0.3 %南昌: 0.3 %台州: 1.9 %台州: 1.9 %合肥: 1.3 %合肥: 1.3 %咸阳: 0.6 %咸阳: 0.6 %哈尔滨: 0.6 %哈尔滨: 0.6 %喀什: 1.0 %喀什: 1.0 %天津: 1.0 %天津: 1.0 %太原: 0.3 %太原: 0.3 %安顺: 0.3 %安顺: 0.3 %宜春: 1.0 %宜春: 1.0 %宣城: 0.3 %宣城: 0.3 %密蘇里城: 0.3 %密蘇里城: 0.3 %常州: 1.3 %常州: 1.3 %常德: 0.3 %常德: 0.3 %广州: 1.0 %广州: 1.0 %张家口: 2.6 %张家口: 2.6 %徐州: 1.6 %徐州: 1.6 %成都: 0.6 %成都: 0.6 %扬州: 0.3 %扬州: 0.3 %昆明: 0.6 %昆明: 0.6 %晋城: 0.6 %晋城: 0.6 %朝阳: 0.3 %朝阳: 0.3 %杭州: 1.9 %杭州: 1.9 %济源: 0.6 %济源: 0.6 %深圳: 0.6 %深圳: 0.6 %温州: 0.3 %温州: 0.3 %湖州: 1.0 %湖州: 1.0 %漯河: 2.2 %漯河: 2.2 %盐城: 0.3 %盐城: 0.3 %石家庄: 1.3 %石家庄: 1.3 %福州: 0.3 %福州: 0.3 %纽约: 0.3 %纽约: 0.3 %绵阳: 0.3 %绵阳: 0.3 %芒廷维尤: 16.0 %芒廷维尤: 16.0 %芝加哥: 0.6 %芝加哥: 0.6 %衢州: 1.0 %衢州: 1.0 %西宁: 10.9 %西宁: 10.9 %西安: 1.0 %西安: 1.0 %贵阳: 0.3 %贵阳: 0.3 %运城: 3.2 %运城: 3.2 %连云港: 0.3 %连云港: 0.3 %遵义: 0.3 %遵义: 0.3 %邯郸: 0.6 %邯郸: 0.6 %郑州: 0.3 %郑州: 0.3 %重庆: 0.3 %重庆: 0.3 %长春: 4.2 %长春: 4.2 %长沙: 0.6 %长沙: 0.6 %阜新: 0.3 %阜新: 0.3 %雷德蒙德: 0.3 %雷德蒙德: 0.3 %青岛: 1.0 %青岛: 1.0 %马鞍山: 0.6 %马鞍山: 0.6 %其他其他Grove CityNormanValencia[]上海东莞临汾临沂佩森保定北京十堰南京南宁南昌台州合肥咸阳哈尔滨喀什天津太原安顺宜春宣城密蘇里城常州常德广州张家口徐州成都扬州昆明晋城朝阳杭州济源深圳温州湖州漯河盐城石家庄福州纽约绵阳芒廷维尤芝加哥衢州西宁西安贵阳运城连云港遵义邯郸郑州重庆长春长沙阜新雷德蒙德青岛马鞍山

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