4.7 Article

Molecular insights into the dissolved organic matter of leather wastewater in leather industrial park wastewater treatment plant

Journal

SCIENCE OF THE TOTAL ENVIRONMENT
Volume 882, Issue -, Pages -

Publisher

ELSEVIER
DOI: 10.1016/j.scitotenv.2023.163174

Keywords

Leather industrial park wastewater treatment; plant; Spectroscopy; Fourier transform ion cyclotron resonance mass; spectrometry; Dissolved organic matter

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Leather wastewater effluent is complex and difficult to degrade. Mixing it with municipal wastewater for treatment is a common practice, but the efficiency of removing dissolved organic matter from leather wastewater remains debated. This study used spectroscopy and mass spectrometry to reveal the composition and transformation of dissolved organic matter during treatment. The results showed differences in properties between leather wastewater and municipal wastewater, and the treatment process had varying removal efficiencies for different types of organic compounds. The study provides theoretical guidance for improving current treatment processes.
Leather wastewater (LW) effluent is characterized by complex organic matter, high salinity, and poor biodegradability. To meet the discharge standards, LW effluent is often mixed with municipal wastewater (MW) before being treated at a leather industrial park wastewater treatment plant (LIPWWTP). However, whether this method efficiently removes the dissolved organic matter (DOM) from LW effluent (LWDOM) remains debatable. In this study, the transformation of DOM during full-scale treatment was revealed using spectroscopy and Fourier transform ion cyclotron resonance mass spectrometry. LWDOM exhibited higher aromaticity and lower molecular weight than DOM in MW (MWDOM). The DOM properties in mixed wastewater (MixW) were similar to those in LWDOM and MWDOM. The MixW was treated using a flocculation/primary sedimentation tank (FL1/PST), anoxic/oxic (A/O) process, secondary sedimentation tank (SST), flocculation/sedimentation tank, denitrification filter (FL2/ST-DNF), and an ozonation con- tact reactor (O3). The FL1/PST unit preferentially removed the peptide-like compounds. The A/O-SST units had the highest removal efficiencies for dissolved organic carbon (DOC) (61.34 %) and soluble chemical oxygen demand (SCOD) (52.2 %). The FL2/ST-DNF treatment removed the lignin-like compounds. The final treatment showed poor DOM mineralization efficiency. The correlation between water quality indices, spectral indices, and molecular-level parameters indicated that lignin-like compounds were strongly correlated with spectral indices and CHOS compounds considerably contributed to the SCOD and DOC. Although the effluent SCOD met the discharge standard, some refrac- tory DOM from LW remained in the effluent. This study illustrates the composition and transformation of DOM and provides theoretical guidance for improving the current treatment processes.

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