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Publikationstyp

Wissenschaftlicher Artikel

Erscheinungsjahr

2019
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Formation and fate of point-source nonextractable DDT-related compounds on their environmental aquatic-terrestrial pathway

Herausgeber

Quelle

Environmental Science & Technology
53 (2019), Heft 3

Schlagwörter

Finanzierungskennzeichen

standardisiertes Finanzierungskennzeichen

Verbundene Publikation

Zitation

ZHU, Xiaojing, Larissa DSIKOWITZKY, Sebastian KUCHER und Mathias RICKING, 2019. Formation and fate of point-source nonextractable DDT-related compounds on their environmental aquatic-terrestrial pathway. Environmental Science & Technology [online]. 2019. Bd. 53 (2019), Heft 3. DOI 10.60810/openumwelt-1924. Verfügbar unter: https://openumwelt.de/handle/123456789/5049
Zusammenfassung englisch
Nonextractable residues (NER) are pollutants incorporated into the matrix of natural solid matter via different binding mechanisms. They can become bioavailable or remobilize during physical-chemical changes of the surrounding conditions and should thus not be neglected in environmental risk assessment. Sediments, soils, and groundwater sludge contaminated with DDXs (DDT, dichlorodiphenyltrichloroethane; and its metabolites) were treated with solvent extraction, sequential chemical degradation, and thermochemolysis to study the fate of NER-DDX along different environmental aquatic-terrestrial pathways. The results showed that DDT and its first degradation products, DDD (dichlorodiphenyldichloroethane) and DDE (dichlorodiphenyldichloroethylene), were dominant in the free extractable fraction, whereas DDM (dichlorodiphenylmethane), DBP (dichlorobenzophenone), and DDA (dichlorodiphenylacetic acid) were observed primarily after chemical degradation. The detection of DDA, DDMUBr (bis(p-chlorophenyl)-bromoethylene), DDPU (bis(p-chlorophenyl)-propene) and DDPS (bis(p-chlorophenyl)-propane) after chemical treatments evidenced the covalent bindings between these DDXs and the organic matrix. The identified NER-DDXs were categorized into three groups according to the three-step degradation process of DDT. Their distribution along the different pathways demonstrated significant specificity. Based on the obtained results, a conceptual model of the fate of NER-DDXs on their different environmental aquatic-terrestrial pathways is proposed. This model provides basic knowledge for risk assessment and remediation of both extractable and nonextractable DDT-related contaminations. © 2019 American Chemical Society