Sorption–desorption hysteresis of phenanthrene – Effect of nanopores, solute concentration, and salinity

• Published in: Chemosphere (Oxford) Vol. 81; no. 7; pp. 961 - 967
• Main Authors: Wu, Wenling, Sun, Hongwen
• Format: Journal Article
• Language: English
• Published: Kidlington Elsevier Ltd 01.11.2010; Elsevier
• Subjects: Absorption; Adsorption; Applied sciences; Desorption; Environmental Pollutants - analysis; Environmental Pollutants - chemistry; Exact sciences and technology; Fresh Water - chemistry; Geologic Sediments - chemistry; Hysteresis; Kinetics; Nanomaterials; Nanopores; Nanostructure; Phenanthrene; Phenanthrenes - analysis; Phenanthrenes - chemistry; Pollution; Saline water; Salinity; Salt water; Seawater - chemistry; Soil - chemistry; Sorbents; Sorption; Sorption; Phenanthrene; Desorption; Nanopores; Hysteresis; Salinity; Organic matter; Hydrocarbon; Fresh water; Polycyclic aromatic compound; Mutagen; Sediments; Persistent organic pollutant; Carcinogen; Kinetics; Sorbent; Organic compounds
• ISSN: 0045-6535; 1879-1298
• DOI: 10.1016/j.chemosphere.2010.07.051

Phenanthrene sorption and desorption from sediment/soil in fresh and saline water were measured, and effects of nanopores, solute concentration, and salinity on sorption–desorption hysteresis were discussed. The extent and kinetics of sorption–desorption hysteresis depend much on the pore distribution of the sorbents, and greater but slower-developed hysteresis occurred on the sorbent with higher specific surface area and more nanopores. In saline water, phenanthrene sorption was enhanced as compared to freshwater, with log K F increasing from 2.84 and 3.08 to 2.96 and 3.33 for the two sorbents, respectively; however, the sorption–desorption hysteresis was weakened, as indicated by the lower hysteresis index in saline water as compared to those in freshwater. In successive desorption, the irreversible sorbed amount of phenanthrene increased with increasing phenanthrene concentration until a maximum ( Q max irr ) was achieved, and the subsequent sorption became reversible. In saline water, Q max irr is much lower (10 mg kg −1) as compared to freshwater (36 mg kg −1), and phenanthrene sorption was almost reversible, especially at high concentrations. N 2 sorption illustrated that soil organic matter had changed to a more condensed conformation in saline water, as indicted by the reduced surface area (from 9.6 to 7.3 m 2 g −1), which is unfavorable for irreversible sorption.