Nitrogen and carbon removal from Fenton-treated leachate by denitrification and biofiltration

Bioresource Technology

Volumn 101, Issue 20, 2010, Pages 7736-7743

  Li, Huosheng ^a   Zhou, Shaoqi ^a   Sun, Yanbo ^a   Lv, Jiang ^a  

^a SOUTH CHINA UNIVERSITY OF TECHNOLOGY   (China)

Author keywords

Biofiltration; Denitrification; Landfill leachate; Nitrogen removal; Response surface methodology (RSM)

Indexed keywords

BIOFILM REACTORS; BIOLOGICAL AERATED FILTER; CARBON REMOVAL; CARBON SOURCE; CENTRAL COMPOSITE DESIGNS; COMBINATION PROCESS; HYDRAULIC RETENTION TIME; LANDFILL LEACHATE; LANDFILL LEACHATES; LEACHATES; LOW COSTS; MODEL PREDICTION; NITROGEN CONCENTRATIONS; PROCESS OPTIMIZATION; RESIDUAL CARBON; RESPONSE SURFACE METHODOLOGY; RESPONSE SURFACE METHODOLOGY (RSM); TOTAL NITROGEN; UPFLOW ANAEROBIC SLUDGE BLANKETS;

BIOFILTERS; BIOFILTRATION; DENITRIFICATION; EFFLUENTS; LEACHING; METHANOL; NITROGEN; NITROGEN REMOVAL; OPTIMIZATION; REFUSE DISPOSAL; SURFACE PROPERTIES;

LEACHATE TREATMENT;

CARBON; METHANOL; NITROGEN;

BIOFILTRATION; CARBON; CHEMICAL OXYGEN DEMAND; DENITRIFICATION; LEACHATE; METHANOL; NITROGEN; POLLUTANT REMOVAL;

ARTICLE; BIOFILTER; BIOFILTRATION; CARBON SOURCE; CHEMICAL OXYGEN DEMAND; COST; DENITRIFICATION; FENTON REACTION; LEACHING; NITROGEN CONCENTRATION; PRIORITY JOURNAL; PROCESS OPTIMIZATION; RESPONSE SURFACE METHOD; UPFLOW REACTOR; WASTE WATER;

CARBON; DENITRIFICATION; FILTRATION; NITROGEN; WASTE WATER;

EID: 77954316158     PISSN: 09608524     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.biortech.2010.05.005     Document Type: Article

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