Feasibility study on an oxidant-injected permeable reactive barrier to treat BTEX contamination: Adsorptive and catalytic characteristics of waste-reclaimed adsorbent

Journal of Hazardous Materials

Volumn 191, Issue 1-3, 2011, Pages 19-25

  Do, Si Hyun ^a   Kwon, Yong Jae ^a   Kong, Sung Ho ^a  

^a Hanyang University   (South Korea)

Author keywords

BTEX; Modified Fenton; Persulfate; PRB; The catalytic degradation; Waste reclaimed adsorbent

Indexed keywords

BTEX; CATALYTIC DEGRADATION; MODIFIED FENTON; PERSULFATE; PRB; WASTE-RECLAIMED ADSORBENT;

ADSORPTION; CALCINATION; DEGRADATION; IRON COMPOUNDS; IRON OXIDES; METAL IONS; OXIDANTS; RATE CONSTANTS; RECLAMATION;

CATALYTIC OXIDATION;

ADSORBENT; BENZENE; ETHYLBENZENE; FERRIC ION; HYDROGEN PEROXIDE; IRON OXIDE; OXALIC ACID; OXIDIZING AGENT; TOLUENE; XYLENE;

ADSORPTION; BOTTOM ASH; CATALYSIS; IRON OXIDE; OXIDATION; PERMEABILITY; PH; REACTIVE BARRIER; SOIL POLLUTION; SURFACE AREA;

ADSORPTION KINETICS; ARTICLE; ASH; CATALYSIS; DEGRADATION; OXIDATION; PERMEABILITY BARRIER; PH; REACTION TIME; SOIL; WASTE COMPONENT REMOVAL; WATER CONTAMINATION;

ADSORPTION; CATALYSIS; ENVIRONMENTAL POLLUTANTS; FEASIBILITY STUDIES; HYDROCARBONS; HYDROGEN-ION CONCENTRATION; OXIDANTS;

EID: 79957748406     PISSN: 03043894     EISSN: 18733336     Source Type: Journal    
DOI: 10.1016/j.jhazmat.2011.03.115     Document Type: Article

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