Insight into the characteristics, removal, and toxicity of effluent organic matter from a pharmaceutical wastewater treatment plant during catalytic ozonation

Wen, Shuhan; Lin, Chen; Li, Weiqi; Ren, Hongqiang; Li, Kan; Wu, Bing; Hu, Haidong; Xu, Ke

doi:10.1038/s41598-018-27921-0

Cited by 20 publications

(6 citation statements)

References 56 publications

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“…Among IWWs, effluents from pharmaceutical plants are considered a big source of environmental pollution (Zhan et al, 2019). In recent years much attention has been given to the degradation of pharmaceutical products (Asif et al, 2017;Zhao et al, 2019), but pharmaceutical WWs can present also a strong colorization (Wen et al, 2018). Many treatments for pharmaceuticals degradation have been developed, but only few of them have been tested for color removal and mostly on synthetic WWs.…”

Section: Introductionmentioning

confidence: 99%

Decolorization and biodegradability of a real pharmaceutical wastewater treated by H2O2-assisted photoelectrocatalysis on TiO2 meshes

Collivignarelli

Abbà

Miino

et al. 2020

Journal of Hazardous Materials

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Section: Introductionmentioning

confidence: 99%

Decolorization and biodegradability of a real pharmaceutical wastewater treated by H2O2-assisted photoelectrocatalysis on TiO2 meshes

Collivignarelli

Abbà

Miino

et al. 2020

Journal of Hazardous Materials

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“…Liu et al [10] observed fast degradation of butyl xanthate at high O 3 dosage of 145.59 mg/(min•L), but the O 3 utilization was not concerned. As the reagent concentration in flotation pulps is usually 10 −3 -10 −4 mol/L [27], the pollutant concentration in flotation effluents is much lower than that of pharmaceutical effluents and petrochemical wastewaters [28,29]. In ozonation, a lower concentration of organics usually leads to a declined O 3 decomposition rate, resulting in lower ozone utilization.…”

Section: Introductionmentioning

confidence: 99%

Degradation of Thiol Collectors Using Ozone at a Low Dosage: Kinetics, Mineralization, Ozone Utilization, and Changes of Biodegradability and Water Quality Parameters

Lin

et al. 2018

Minerals

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Ozonation at a high O3 dosage can achieve high efficiencies in removing flotation reagents but it has a low ozone-utilization rate. The ozonation of potentially toxic thiol collectors (potassium ethyl xanthate (EX), sodium diethyl dithiocarbamate (SN-9), O-isopropyl-N-ethyl thionocarbamate (Z-200) and dianilino dithiophoshoric acid (DDA)) was investigated in an ozone-bubbled reactor at a low O3 dosage of 1.125 mg/(min·L). The degradation kinetics, mineralization, ozone utilization, changes of biodegradability, and water quality parameters were studied, and the degradation behaviors of four collectors were compared. Thiol collectors could be effectively degraded with a removal ratio of >90% and a mineralization ratio of 10‒27%, at a low O3 dosage. The ozonation of thiol collectors followed the pseudo first-order kinetics, and rate constants had the order of kSN-9 > kEX > kZ-200 > kDDA. The Z-200 and DDA were the refractory flotation reagents treated in the ozonation process. After ozonation, the biodegradability of EX, SN-9, and DDA solutions was remarkably raised, but the biodegradability of Z-200 only increased from 0.088 to 0.15, indicating that the Z-200 and its intermediates were biologically persistent organics. After ozonation, the solution pH decreased from 10.0 to 8.0‒9.0, and both the conductivity and oxidation-reduction potential increased. The ozone utilization ratio in decomposing thiol collectors was above 98.41%, revealing almost complete usage of input O3. The results revealed that thiol collectors could be effectively degraded by O3, even at a low dosage, but their degradation behaviors were quite different, due to intrinsic molecular properties.

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“…Also, there is a wide scope of surface-functionalization of nanomaterials which may increase their catalytic affinity towards target compounds, enhancing chemical and environmental stability and promoting reuse [43]. Currently, the most exploited nanomaterials for wastewater treatments include nanostructured carbon based catalysts i.e., carbon nanotubes, graphene, graphene oxide, nano-adsorbents, metal oxides nanoparticles, nano-assisted advanced oxidation processes, and nanofiltration membranes [30,[44][45][46][47]. Moreover, the contemporary technologies also tested the blend characteristics of more than one nanomaterial for exhibiting multifacet properties in the resulting nanocomposites.…”

Section: Advanced Treatment Methods Using Nano-materialsmentioning

confidence: 99%

Removal of Pharmaceutical Contaminants in Wastewater Using Nanomaterials: A Comprehensive Review

Chauhan

Sillu

Agnihotri

2019

CDM

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Background: The limitless presence of pharmaceutical contaminants in discharged wastewater has emerged as a threat to aquatic species and humans. Their presence in drinking water has although raised substantial concerns, very little is known about the fate and ecological impacts of these pollutants. As a result, these pollutants are inevitably introduced to our food chain at trace concentrations. Unfortunately, the conventional wastewater treatment techniques are unable to treat pharmaceuticals completely with practical limitations. The focus has now been shifted towards nanotechnology for the successful remediation of these persistent pollutants. Thus, the current review specifically focuses on providing readers brief yet sharp insights into applications of various nanomaterials for the removal of pharmaceutical contaminants. Methods: An exhaustive collection of bibliographic database was done with articles having high impact and citations in relevant research domains. An in-depth analysis of screened papers was done through standard tools. Studies were categorized according to the use of nanoscale materials as nano-adsorbents (graphene, carbon nanotubes), nanophotocatalysts (metal, metal oxide), nano-filtration, and ozonation for promising alternative technologies for the efficient removal of recalcitrant contaminants. Results: A total of 365 research articles were selected. The contemporary advancements in the field of nanomaterials for drinking and wastewater treatment have been thoroughly analyzed along with their future perspectives. Conclusion: The recommendations provided in this article will be useful to adopt novel strategies for on-site removal of the emerging contaminants in pharmaceutical effluents and related industries.

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Insight into the characteristics, removal, and toxicity of effluent organic matter from a pharmaceutical wastewater treatment plant during catalytic ozonation

Cited by 20 publications

References 56 publications

Decolorization and biodegradability of a real pharmaceutical wastewater treated by H2O2-assisted photoelectrocatalysis on TiO2 meshes

Decolorization and biodegradability of a real pharmaceutical wastewater treated by H2O2-assisted photoelectrocatalysis on TiO2 meshes

Degradation of Thiol Collectors Using Ozone at a Low Dosage: Kinetics, Mineralization, Ozone Utilization, and Changes of Biodegradability and Water Quality Parameters

Removal of Pharmaceutical Contaminants in Wastewater Using Nanomaterials: A Comprehensive Review

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