Journal
ULTRASONICS SONOCHEMISTRY
Volume 20, Issue 6, Pages 1401-1407Publisher
ELSEVIER
DOI: 10.1016/j.ultsonch.2013.04.007
Keywords
Sulfamethazine; Sonolytic degradation; Operational parameters; Additives; Products
Categories
Funding
- National Natural Science Foundation of China [51108327]
- National Major Project of Science 82 Technology Ministry of China [2012ZX07403-001]
- Ministry of Housing and Urban-Rural Development [2009-K7-4]
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In this study, the major factors affecting sonolytic degradation of sulfamethazine (SMT), a typical pharmaceutically active compound, in water were evaluated. The factors tested included two operational parameters (i.e. initial SMT concentration and ultrasonic power), three dissolved gases (i.e. Ar, 02 and N-2), five most frequently found anions in water (NO3-, Cl-, SO42-, HCO3- and Br-), ferrous ion (Fe2+, and four alcohols (methanol, ethanol, isopropyl alcohol, tert-butyl alcohol). Typically, the degradation rate was increased with the increasing initial SMT concentration and power. The degradation rate was accelerated in the presence of argon or oxygen, but inhibited by nitrogen. Effects of anions on the ultrasonic treatment were species-dependent. The SMT degradation rate was slightly inhibited by NO3-, Cl-, and, SO42- but significantly improved by HCO3- and Br-. The negative effects of alcohols acted as hydroxyl radicals scavengers with the following order: tert-butyl alcohol > isopropyl alcohol > ethanol > methanol. The synergetic effect of ferrous ion was mainly due to production of additional hydroxyl radicals (center dot OH) through Fenton chemistry. LC/MS/MS analysis indicated that the degradation of SMT by ultrasonic irradiation is mainly ascribed to center dot OH oxidation. Of interest, although the SMT could be rapidly degraded by ultrasonic irradiation, the degradation products were rarely mineralized. For example, similar to 100% of 180 mu M SMT was decomposed, but only 8.31% TOC was reduced, within 2 h at an irradiation frequency of 800 kHz and a power of 100W. However, the products became much biodegradable (BOD5/COD was increased from 0.04 to 0.45). Therefore, an aerobic biological treatment may be an appropriate post-treatment to further decompose the SMT degradation products. (C) 2013 Elsevier B.V. All rights reserved.
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