Your search keyword '"CHEMICAL oxygen demand"' showing total 45,120 results

1. Prediction of Chemical Oxygen Demand in New Nicosia Waste Water Treatment Plant Using Hybrid Metro-Environmental Data

Author

Mubarak, Auwalu Saleh, Uzun, Berna, Ameen, Zubaida Said, Ozsahin, Dilber Uzun, Abba, Sani Isa, Yakub, Mahadi Lawal, LaMoreaux, James W., Series Editor, Gökçekuş, Hüseyin, editor, and Kassem, Youssef, editor

Published

2025

2. Effects of Hybrid Metrological and Environmental Data for the Prediction of Chemical Oxygen Demand in Waste Water Treatment Plant Using Explainable AI Models

Author

Ozsahin, Dilber Uzun, Ameen, Zubaida Said, Uzun, Berna, Mubarak, Auwalu Saleh, Abba, Sani Isa, Lawal, Salisu M., LaMoreaux, James W., Series Editor, Gökçekuş, Hüseyin, editor, and Kassem, Youssef, editor

Published

2025

3. Pre-treatment of composite industrial wastewater by Fenton and electro-Fenton oxidation processes.

Author

Omar, Basma M., Zyadah, Mohamed A., Ali, Menna Y., and El-Sonbati, Mervat A.

Abstract

The present study aims to characterize three industrial wastewater samples collected from petrochemical, food and beet sugar industries to determine the pollution potential and select the appropriate pre-treatment approach. According to the biodegradability profile of the multi-sourced mixed (composite) sample, the advanced oxidation process (AOPs) namely, Fenton (F) and Electro-Fenton (EF) were adopted as pre-treatment techniques and the operating parameters such as time, type of electrodes, pH, voltage, iron and H2O2 concentrations were critically examined. Analysis of Variance (ANOVA) was conducted to compare the performance efficiency of F& EF AOPs for treating the composite samples and the total operating costs for both approaches were assessed. The results revealed that, the initial values of the composite sample were 7.11, 19.2, 32.6, 19.3, 937, 1512, 860, 3.9, 2110 and 2.34 for pH, Total Dissolved Solids (TDS), Electrical Conductivity (EC), Salinity, BOD, COD, Oil and grease (O&G), Total Phosphorous (TP), Total Suspended Solids (TSS) and Total Kjeldahl Nitrogen (TKN), respectively. In addition, EF process achieved more removal efficiency for COD, O&G, BOD, TSS, and TKN (84.3%, 69%, 85%, 72% and 71.27%) compared to Fenton which displayed 78.43%, 66%, 69%, 70.1%, and 61%, respectively. Moreover, there are statistically significant differences (p < 0.05) between the initial and final (pretreated) values of the composite industrial wastewater for the addressed parameters and EF was significantly (p < 0.05) more effective than F process. The total operating costs were 3.117 and 2.063$ for F and EF, respectively, which confirmed that EF is more efficient and cost effective than F process. It was concluded that electro-Fenton process is favorable, eco-friendly and cost-effective option for pretreating real complicated multi-sourced industrial wastewater. The present study demonstrated a new avenue for achieving efficient management of industrial wastewater generated from similar industries. [ABSTRACT FROM AUTHOR]

Published

2024

4. Study on the characteristics of cavitation and COD removal of an addendum rotational hydrodynamic cavitation reactors.

Author

Zhou, Faqi, Luo, Zhiwei, Wu, Xianbo, Xing, Yiming, Fu, Shuangcheng, and Yuan, Huixin

Subjects

*CHEMICAL oxygen demand, *CAVITATION, *WASTEWATER treatment, *KINETIC energy, *AGRICULTURE

Abstract

This paper presented an addendum rotational hydrodynamic cavitation reactors (ARHCR) that enabled circumferential shear cavitation, axial cavitation, and the Venturi effect, thus increasing cavitation efficiency. The experiments on hydroxyl (·OH) release and chemical oxygen demand (COD) removal demonstrate the feasibility of cavitation performance characterization and COD removal rate. The findings indicate that the COD removal rate can reach a maximum value of 28% or 30% with an increase in flow rate or rotating speed, respectively. Specifically, the maximum values were achieved at a rotation speed of 2,500 rpm or a flow rate of 1.0 m3·h−1. Based on the mechanism of the addendum cavitation, the wedge angles, and the crucial structural parameters, were examined for optimizing cavitation performance. The results revealed that the cavitation number and cavitation bubble were significantly influenced by wedge angles, as well as the efficiency of cavitation energy. The mechanical shear of fluid was enhanced by wedge angles, resulting in constant compression and release of fluid with increased kinetic energy. This led to stronger effects on bulge blocks, and the formation of vortexes that rebounded constantly, resulting in lower pressure areas and expanded regions of cavitation. Among the wedge angles tested, the wedge angle of 15° exhibited the highest cavitation bubbles with a maximum value of 46%. This was 31% higher than the grooves‐type cavitator reported. Furthermore, the cavitation performance was extremely improved with a wedge angle of 15°, as corresponding with the maximum efficiency of cavitation energy. These explorations provide references for the removal of COD in industrial and agricultural wastewater, as well as the development of novel reactors for wastewater treatment. [ABSTRACT FROM AUTHOR]

Published

2024

5. Treatment of hydrocarbon marine pollution with cloud point extraction.

Author

Ghouas, H., Haddou, B., Canselier, J. P., and Kameche, M.

Subjects

*NONIONIC surfactants, *MARINE pollution, *OCEAN temperature, *CHEMICAL oxygen demand, *RESPONSE surfaces (Statistics)

Abstract

The release of hydrocarbons (HC) into the marine environment has serious consequences, both economically and ecologically. This work presents an efficient process to remove HC pollution from seawater: cloud point extraction (CPE), considered to be a reliable, inexpensive, and environmentally friendly method, using the readily biodegradable nonionic surfactants Lutensol ON30 and Tergitol 15‐S‐7. A real salt water sample with a high chemical oxygen demand (COD = 1700 mg O2/L) was thus treated. First, the phase diagrams of the binary systems (water–surfactant), and the pseudo‐binary systems (water–surfactant–HC), were determined. Second, after a 24 h settling time, considered as optimal, the extraction results, that is, residual soluble COD, residual percentage of surfactant in the dilute phase and volume fraction of coacervate at equilibrium, were expressed in terms of temperature and initial surfactant concentration. For each parameter, the results obtained were modeled using the response surface methodology and represented on three‐dimensional diagrams. They show that the COD can be reduced to 10 and 15 mg O2/L, using Lutensol ON30 and Tergitol 15‐S‐7, respectively, under seawater temperature conditions. Finally, it was shown that the surfactant can be recycled. The present work demonstrates that CPE can reduce the HC content of seawater on a laboratory scale. [ABSTRACT FROM AUTHOR]

Published

2024

6. Pontederia crassipes utilization for dual phytoremediation and adsorption in greywater treatment: a techno-economic and sustainable approach.

Author

Azabo, Morish, Abdelhaleem, Amal, Fujii, Manabu, and Nasr, Mahmoud

Subjects

*INTERNAL rate of return, *NET present value, *CHEMICAL oxygen demand, *SUSTAINABILITY, *PAYBACK periods, *GRAYWATER (Domestic wastewater)

Abstract

While phytoremediation has been widely employed for greywater treatment, this system suffers from the transfer of considerable amounts of surfactants to the aquatic environment through partially treated effluent and/or exhausted plant disposal. Hence, this study focuses on greywater phytoremediation followed by recycling the spent plant for preparing an adsorbent material used as post-treatment. P. crassipes was used to operate a phytoremediation unit under 23 °C, 60% relative humidity, plant density (5–30 g/L), dilution (0–50%), pH (4–10), and retention time (3–15 days). The optimum condition was 12.7 g/L density, 34.0% dilution, pH 8.4, and 13 days, giving chemical oxygen demand (COD), surfactant, and NH4-N removal efficiencies of 94.62%, 90.45%, and 88.09%, respectively. The exhausted plant was then thermally treated at 550 °C and 40 min to obtain biochar used as adsorbent to treat the phytoremediation effluent. The optimum adsorption process was biochar dosage of 1.51 g/L, pH of 2.1, and 137 min, providing a surfactant removal efficiency of 92.56%. The final discharge of this phytoremediation/adsorption combined process contained 8.30 mg/L COD, 0.23 mg/L surfactant, and 0.94 mg/L NH4+-N. Interestingly, this approach could be economically feasible with a payback period of 6.5 years, 14 USD net present value, and 8.6% internal rate of return. NOVELTY STATEMENT: The research succeeded in treating greywater by phytoremediation followed by recycling the exhausted P. crassipes plant to prepare an adsorbent material used in the post-treatment phase, giving an economically feasible scenario with 6.5-year payback period. [ABSTRACT FROM AUTHOR]

Published

2024

7. Review on applicability of constructed wetlands in the South Asian region focusing on roles of media, macrophytes, microbes, pre-treatment and post-treatment.

Author

Karki, Bhesh Kumar

Subjects

*TOTAL suspended solids, *CONSTRUCTED wetlands, *BIOCHEMICAL oxygen demand, *EMERGING contaminants, *CHEMICAL oxygen demand

Abstract

This article examines the utilization and advancements of constructed wetlands (CWs) in South Asia (SA), focusing on their roles, costs, and efficacy enhancements through pre- and post-treatment units for various pollutants. Notable findings include Phragmites and Canna species as commonly used macrophytes, achieving high removal rates for various pollutants. CWs consistently remove total suspended solids, biochemical oxygen demand, chemical oxygen demand, emerging contaminants, and antimicrobial resistant bacteria at substantial rates. Anaerobic baffled reactors are effective pretreatment devices for high-strength wastewater. Moreover, CWs exhibit lower operational and maintenance costs compared to conventional treatment methods. However, the bibliometric analysis reveals limited regional cooperation in SA. Key challenges identified include the absence of guidelines for media, vegetation, and maintenance. The review underscores the necessity for further research in optimizing CWs' efficiency through land area management, plant selection, and enhanced design and operation and maintenance protocols. [ABSTRACT FROM AUTHOR]

Published

2024

8. Preparation of low‐cost peridotite ceramic microfiltration membrane for treating industrial wastewater.

Author

Harrati, Achraf, Arkame, Youssef, Adlane, Sanaa, Essate, Ahlam, Achiou, Brahim, El Bouari, Abdeslam, Aaddane, Abdelleh, Alami Younssi, Saad, and Sadik, Chaouki

Subjects

*CHEMICAL oxygen demand, *PERIDOTITE, *MICROFILTRATION, *WASTEWATER treatment, *POROSITY

Abstract

The aim of this work is to fabricate a low‐cost ceramic microfiltration (MF) membrane made from a new geomaterial named peridotite. The membrane was prepared by uniaxial pressing and followed by sintering. The effect of sintering temperature, in the range of 1100–1225°C, on the permeability, porosity, mechanical strength, and pore size was investigated. The optimized MF membrane sintered at 1200°C exhibits 1198.9 L h−1 m−2 bar−1 of permeability, 36.41% of porosity, 12.9 MPa of mechanical strength, and 1.56 µm of pore size. The prepared membrane was used for the MF treatment of dairy wastewater. It was found that the membrane is able to remove 88.56% and 69.54% of turbidity and chemical oxygen demand, respectively. Furthermore, the cost of the peridotite membrane was estimated to be $10.3 m−2. [ABSTRACT FROM AUTHOR]

Published

2024

9. Furan-2-carbaldehyde removal by electrocoagulation process employing scrap iron packed as a sacrificial anode.

Author

Rahmani, Ali Reza, Azarian, Ghasem, Jamshidi, Reza, and Dehdar, Ali

Subjects

*CHEMICAL oxygen demand, *BATCH reactors, *ENERGY industries, *OPERATING costs, *ENERGY consumption

Abstract

In this study, a new sacrificial anode comprised of scrap iron packaged in a polyethylene mesh chamber for Furan-2-carbaldehyde removal using the electrocoagulation (EC) process was fabricated. Therefore, the influences of different operational parameters, such as solution pH, current intensity, initial Furan-2-carbaldehyde concentration, and detention time on the process performance at the batch hydraulic reactor were investigated. Due to the large surface area of the anode, the applied current intensity was low, which led to high efficiency for the Furan-2-carbaldehyde removal (> 97%) at low operating voltage and energy consumption (5.4 kWh/m3). The experimental results corresponded well to the first-order kinetic model. The mineralization values for Furan-2-carbaldehyde using the EC process were 46.5% and 75.5% for total organic carbon (TOC) and chemical oxygen demand (COD), respectively. Moreover, the EC process shows the biodegradability was significantly increased compared to the initial solution after 120 min of reaction time. Based on the LC-MS analysis, the major produced intermediates and the degradation pathway of Furan-2-carbaldehyde were proposed. Consequently, on the contrary plate electrodes, the use of scrap iron as a sacrificial anode increases efficiency and reduces the total required operating costs for energy and electrodes. [ABSTRACT FROM AUTHOR]

Published

2024

10. Optimization of pollutants removal from anaerobically digested dairy wastewater by electro-oxidation process: a response surface methodology modeling and validation.

Author

Das, Ashish Kumar, Reza, Arif, and Chen, Lide

Subjects

*SUSTAINABILITY, *RESPONSE surfaces (Statistics), *WASTEWATER treatment, *POLLUTION, *CHEMICAL oxygen demand, *LEAD dioxide

Abstract

The release of anaerobically digested dairy wastewater (ANDDW) without a treatment can lead to severe environmental pollution, prompting the exploration of effective and sustainable treatment methods. Amidst various wastewater treatment approaches, the electro-oxidation (EO) process is considered as a promising, clean, and adaptable solution. In this study, the major operational parameters viz. current density, electrolyte concentration, treatment time, and mixing speed of an EO comprising Ti/PbO2 anode and stainless-steel cathode, were optimized using response surface methodology (RSM) for efficient removal of chemical oxygen demand (COD), ammonia nitrogen (NH3-N), total phosphorus (TP), orthophosphate (OP), total nitrogen (TN), and total Kjeldahl nitrogen (TKN) from ANDDW. Optimal conditions were identified as a current density of 90 mA cm−2, 0.08% electrolyte concentration, 180 min treatment time, and 400 rpm mixing speed. Under the optimum conditions, the COD, NH3-N, TP, OP, TN, and TKN removal efficiencies were 78.36, 63.93, 87.41, 92.39, 67.01, and 81.42%, respectively. Furthermore, the reaction rate followed the first-order kinetic model for the pollutants removal with correlation coefficients (R2) close to 1. The findings highlight the potential of using the EO process to treat high pollutant-laden ANDDW and encourage further studies to confirm the corresponding outcomes on a pilot scale. [ABSTRACT FROM AUTHOR]

Published

2024

11. Unraveling the pyridinic nitrogen vacancy in carbon nitride for photo-self Fenton-like purification of organic contaminants.

Author

Yue, Junpeng, Yang, Hanpei, Liu, Chen, Wang, Shi, and Wang, Lina

Subjects

*NITRIDES, *POLLUTANTS, *WATER purification, *BIOCHEMICAL oxygen demand, *HABER-Weiss reaction, *CHEMICAL oxygen demand, *ATMOSPHERIC oxygen

Abstract

Pyridinic nitrogen vacancy in carbon nitride for photo-self Fenton-like purification of organic contaminants. [Display omitted] • Carbon nitride with pyridinic nitrogen vacancy was successfully prepared. • Pyridinic nitrogen vacancy promotes charge transfer and activating O 2 into H 2 O 2. • Pyridinic nitrogen vacancy accelerates carbon nitride to adsorb organic contaminants. • Photo-self Fenton-like reaction for photocatalytic degradation of organics. This work reports a carbon nitride with pyridinic nitrogen-vacancy (N 2C V-CN), which purifies organic contaminants via an in-situ photo-self Fenton-like reaction. Experiments and calculations demonstrated that the nitrogen-vacancy induces lone-paired (LP) and symmetry-unpaired electrons, promoting the formation of low-energy LP-π hybridized orbitals and helping to overcome the pairing energy required for oxygen to accept electrons. Furthermore, the nitrogen-vacancy accelerates film and intra-particle diffusion rates of organic contaminants on N 2C V-CN, creating beneficial conditions for reactive oxide species to mineralize organic contaminants. Under sunlight and atmospheric oxygen, a photo-self Fenton-like reaction involving proton-coupled electron transfer occurred on the surface of N 2C V-CN. Furthermore, by integrating photocatalysis with flocculation, about 99.1 % suspended substance, 45.5 % chemical oxygen demand, and 38.4 % biological oxygen demand were reduced from polluted river-water. Constructing N 2C V-CN and understanding its crucial role offer theoretical and methodological insights into the in-situ purification of contaminated water bodies. [ABSTRACT FROM AUTHOR]

Published

2024

12. Enhancing Biogas Production Through the Co-Digestion of Fish Waste (FW) and Water Hyacinth (WH) Using Cow Dung as an Inoculum: Effect of FW/WH Ratio.

Author

Nahar, Gaurav, Koley, Apurba, Garai, Subhadip, Balachandran, Srinivasan, and Ross, Andrew B.

Abstract

The current investigation explores biogas production from water hyacinth (WH) and fish waste (FW) with cow dung (CD) as an inoculum source in two scenarios. In the first scenario, the optimization of mono-digestion was performed where the effect of WH/FW (substrates) with CD (inoculum) in varied ratios of 1:1, 1:2, 2:1, and 3:1 was observed to enhance the biogas production. In the second scenario, the optimization of co-digestion using both FW and WH as substrates in different ratios (1:1, 1:2, and 2:1) with a fixed amount of inoculum was studied. The experiments were conducted in 500 mL digesters in duplicate under mesophilic conditions. Under mono-digestion conditions for FW, the digester operating with FW/CD in a 1:2 ratio demonstrated the highest biogas yield of 970 ± 14.1 mL/g VS, containing 610 CH4 mL/g VS, while in WH, the WH/CD ratio of 1:1 exhibited the highest biogas yield of 925 ± 49.4 mL/g VS, with a methane content of 440 CH4 mL/g VS. The co-digestion of the WH/FW ratio (1:1) showcased the highest biogas production of 1655 ± 91.92 mL/g VS, accompanied by 890 ± 70.7 CH4 mL/g VS. This was followed by the 1:2 and 2:1 ratio, yielding 1400 ± 56.5 and 1140 ± 169.7 mL/g VS. of biogas and 775 and 585 CH4 mL/g VS, respectively. The CD and WH mixture at a 1:1 ratio demonstrated the most significant decrease in chemical oxygen demand (COD), reaching 91.68%. COD reductions over 80% in all combinations were observed in all instances. Anaerobic digestion (AD) simulations were validated using the Gompertz model, with high correlation coefficient values (R-squared) above 0.99 for all of the studied ratios, depicting a significant correlation between experimental data and model predictions. The propionic to acetic acid ratio did not cross the threshold level, indicating no inhibition of methane production. ANOVA analysis of biogas production between the co-digestion and mono-digestion of substrates showed non-significant results (p > 0.310 and p > 0.824, respectively), while overall digestion was significant (p < 0.024), indicating efficiency variations among substrates. Paired sample t-tests revealed substantial differences between co-digestion ratios, which were also significant. [ABSTRACT FROM AUTHOR]

Published

2024

13. Biopolymeric Composite Columns for Improving Water Quality in a Freshwater Stream Receiving Wastewater Treatment Plant Effluents.

Author

Akpınar, Şahin, Gurbuz, Fatma, Özcan, Samet, and Odabaşı, Mehmet

Subjects

COMPOSITE columns, SEWAGE disposal plants, CHEMICAL oxygen demand, WATER quality, POLLUTANTS

Abstract

Inefficiently treated wastewater, which contains a high concentration of pollutants, is hazardous when it is mixed with the clean water of rivers and lakes. Nitrate in particular is a major global problem that leads to eutrophication and poses a threat to both aquatic ecosystems and human health. To address this issue, this work assessed the efficiency of polymeric cryogel (PC) and biopolymer (EPS)-blended composites (EPS@PC) in removing nitrates. Tests were also conducted to quantify the decrease in phosphate, chloride ions, and chemical oxygen demand (COD) in real water samples taken from the Ankara stream, which receives effluents from both urban (UWTP) and industrial (IWTP) wastewater treatment plants. Five different columns with varying adsorptive properties were prepared, some of which were combined with iron. The EPS-@PC-C5 column demonstrated the highest adsorption ratio for nitrate removal compared to the other tested columns. The EPS@PC-C5 achieved a high removal efficiency of 126.38 mg nitrate/g and showed COD reduction ranging from 60.2 to 94.1%. The removal ratio of chloride concentration varied between 56.0 and 75.7%, while the removal of phosphates ranged from 87 to 99%. Columns composed of EPS (EPS@PC) with both negatively and positively charged ligands are dependable and suitable options for water remediation. [ABSTRACT FROM AUTHOR]

Published

2024

14. An investigation into a petrochemical effluent treatment using a membrane biological reactor.

Author

Ahmadpour, Amin, Bozorgian, Alireza, Eslamimanesh, Ali, and Mohammadi, Amir H.

Subjects

WATER purification, MEMBRANE reactors, CHEMICAL oxygen demand, BIOLOGICAL membranes, SUSPENDED solids, UPFLOW anaerobic sludge blanket reactors

Abstract

In this study, a sample from the effluent of lower salt section of Fajr Petrochemical Company (located in southwest of Iran) has been treated using an in-house designed and built-up membrane biological reactor/bioreactor (MBR). Effective parameters in the performance of the unit have been determined, and their optimal values have been obtained through an experimental design approach. It is shown that process parameters including mixed liquor volatile suspended solids (MLVSS), hydraulic retention time (HRT), membrane type as well as their combined parameters exhibit considerable influence on the output chemical oxygen demand (COD) of purification process. The results of modeling with design expert test software show that the term AB (interaction of HRT and MLVSS) has the most important effect and the effect of bioreactor change does not have a significant effect on changes in COD. Furthermore, the optimization procedure shows that the maximum COD removal percentage of 94.36 using cellulose membrane (CAS) can be achieved under operating conditions of HRT = 1 h and MLVSS = 11,200 mg/L. [ABSTRACT FROM AUTHOR]

Published

2024

15. Characterization of Landfill Leachate and their Toxic Effects on Germination and Seedling Growth of Various Plant Species - A Case Study.

Author

Taha, Rima Saed, AlKassasbeh, Jaffar Y. M., Alharbi, Omar M. L., Bouqellah, Nahla A., Sweity, Amer, and Al-Shawabkeh, Jumanah D.

Subjects

SANITARY landfills, POISONS, PROBIT analysis, CHEMICAL oxygen demand, CUCUMBERS, CABBAGE

Abstract

Leachate generated from landfills contains many toxic contaminants, such as dissolved organics, inorganic salts, ammonia, and heavy metals, which impact the surrounding environmental systems. This study characterized the AL-Mufarrihat Sanitary Landfill (MSL) leachate in Al-Medinah Al-Munawwarh (MM) province, Saudi Arabia, by analyzing important physicochemical parameters. Phytotoxicity was assessed using various higher plant bioassays, namely, cucumber (Cucumis sativus L.), tomato (Lycopersicum esculentum L.), cabbage (Brassica oleracea var. capitata L.), and corn (Zea mays L.). The effective concentration of seed germination represented by EC50 was calculated using a USEPA computer program based on Finney's Probit analysis method. Selected phytotoxicity test endpoint parameters, namely relative seed germination (RSG), relative root elongation (RRE), and germination index (GI) were determined. The tested leachate exhibited low concentrations of heavy metals, whereas high levels of chemical oxygen demand (COD) and ammonia nitrogen (NH3-N) were recorded. The mean EC50 values for MSL leachate exposed to B. oleracea, L. esculentum, C. sativus, and Z. mays were 2.66%, 3.12%, 4.27%, and 5.22%, respectively. These values indicate that B. oleracea was the most sensitive bioassay, whereas Z. mays was the least sensitive. All tested bioassays showed severe phytotoxic responses to the exposed higher leachate concentrations, represented by complete inhibition for RSG, RRE, and GI. Lower leachate concentrations exhibited stimulatory effects on RSG, whereas RRE and GI were hindered, even at these lower concentrations. The results revealed that although RSG and RRE were effective and promising parameters in phytotoxicity evaluation, GI was the most responsive parameter for phytotoxicity assessment. The high levels of organic and inorganic compounds in the leachate are likely the primary cause of the phytotoxicity observed in the bioassays. The results of this study highlight the pollution potential of landfill leachate in Saudi Arabia and will furnish supplementary reference information for hazard assessment and future leachate management. [ABSTRACT FROM AUTHOR]

Published

2024

16. Effects of Dosage and Stirring Speed Variations in the Use of Bittern as a Natural Coagulant to Remove Biological Oxygen Demand, Chemical Oxygen Demand, Total Suspended Solids and Dye Concentrations from Batik Industry Wastewater.

Author

Fitriani, Nurina, Supriyanto, Agus, Jariyah, Niswatun Indana, Putriadji, Rachely Annisa Dwi, Pratama, M. Bagas Pramudya, Wan Jusoh, Hajjar Hartini, Ismail, Azimah, and Kurniawan, Setyo Budi

Subjects

TOTAL suspended solids, BIOCHEMICAL oxygen demand, CHEMICAL oxygen demand, PEARSON correlation (Statistics), TWO-way analysis of variance, SUSPENDED solids

Abstract

This study aimed to determine the effect of bittern coagulant dosage and rapid stirring speed on reducing the concentrations of biological oxygen demand (BOD), chemical oxygen demand (COD), total suspended solids (TSS), and dye absorbance in batik industry wastewater, as well as to identify the optimum coagulant dosage and stirring speed. Wastewater samples were collected from a batik industry in the batik center of Sidoarjo, East Java, Indonesia. Dosage variations of 5%, 10%, 15%, and 20% were tested alongside rapid stirring speeds of 100 rpm, 130 rpm, and 160 rpm. The study was conducted on a laboratory scale using the jar test method. Initial wastewater characteristics showed BOD, COD, TSS, and dye absorbance concentrations of 185.68 ± 29.34 mg/L, 10.091 ± 363.24 mg/L, 2.231.33 ± 155.55 mg/L, and 0.212 ± 0.02, respectively. Statistical analysis using the Pearson correlation test and Two-Way ANOVA revealed that variations in coagulant dosage and stirring speed significantly impacted the reduction percentages of BOD, COD, TSS, and dye absorbance. The optimal coagulant dosage was found to be 5%, and the optimal stirring speed was 100 rpm, with reduction percentages for BOD, COD, TSS, and dye absorbance being 80.32%, 65.86%, 92.35%, and 70.77%, respectively. [ABSTRACT FROM AUTHOR]

Published

2024

17. Adsorption performance of ammonium molybdate modified Salix wood flour biochar for the treatment of monosodium glutamate wastewater.

Author

He, Hao, Li, Xi-lin, Zhao, Bai-yun, Liu, Xiao-kai, Zhou, Li-juan, Zhao, Xuan, Wang, Chen-xu, and Wang, Li

Subjects

MONOSODIUM glutamate, WOOD flour, CHEMICAL oxygen demand, WASTEWATER treatment, POLLUTANTS

Abstract

The problem of wastewater pollution in the production of monosodium glutamate (MSG) is becoming more and more serious. A novel type of chemically modified Salix psammophila powder charcoal (SPPCAM) was synthesized to address the chemical oxygen demand (COD) and ammonia nitrogen (NH3-N) in MSG wastewater. SPPCAM was prepared by carbonization method, in which inorganic ammonium molybdate (AM) was used as modifier and Salix psammophila powder (SPP) was used as raw material. Under optimal treatment conditions, maximum removal rates (removal capacities) of 45.9% (3313.2 mg·L−1) for COD and 29.4% (23.2 mg·L−1) for NH3-N in MSG wastewater were achieved. The treatment results significantly outperforming the unmodified Salix psammophila powder charcoal (SPPC), which only achieved removal rates (removal capacities) of 10.6% (763.9 mg·L−1) for COD and 12.9% (10 mg·L−1) for NH3-N. SPPC and SPPCAM before and after preparation were analysed by FT-IR and XRD, and Mo ions in the form of Mo2C within SPPCAM were successfully loaded. SEM, EDS-Mapping, BET, and other methods were used to analyse SPPCAM before and after MSG wastewater treatment, demonstrating that SPPCAM effectively treated organic pollutants in monosodium glutamate wastewater. The NH3-N in the treated MSG wastewater has reached the standard of safe discharge. [ABSTRACT FROM AUTHOR]

Published

2024

18. Effect of predatory bacterial mixtures on biolysis of waste activated sludge to improve dewatering performance.

Author

Wu, Zeyu, Gao, Huan, Chen, Zhoukai, Su, Wenqiang, Jie, Yongfang, Zhu, Jian, and Yu, Ran

Subjects

CHEMICAL oxygen demand, WASTEWATER treatment, PROTEOBACTERIA, LYSIS, MIXTURES

Abstract

The generation of surplus sludge during biological wastewater treatment has become a prevalent issue, necessitating the development of a dewatering approach that is efficient, economically feasible, and ecologically sound. Bdellovibrio-and-like-organisms (BALOs) are obligatory parasitic bacteria that prey on an array of bacteria. In this study, different BALO strains were isolated and purified from waste activited sludge (WAS). Anti-predation host strains were applied to screen the BALO strains with different host-range to minimize the overlap of the biolysis prey spectrum. In addition, the BALO strains with different host preferences were mixed for sludge biolysis treatment efficiency comparison. The results indicated that the capillary suction time and the bound water content in the WAS treated with the mixed BALOs were significantly decreased by 25.9% ± 1.7% and 5.2% ± 1.2%, respectively, compared to those treated with the single BALO strain. The soluble chemical oxygen demand concentration in the mixed BALOs treated group was increased by 31.2% ± 0.7% than that treated with the single strain. The findings indicate that the mixed strains used in the treatment process resulted in a notable enhancement of both sludge dewatering performance and lysis degree. In addition, the abundance of Proteobacteria treated with the BALO mixtures decreased by 69.1% than the single strain treated one which demonstrated that the BALO mixture expanded the sludge host lysis spectrum. This study revealed the different effects of single and mixed strains on sludge community structure, suggesting that the BALO host-range expansion is crucial to further improve sludge dewatering performances. [ABSTRACT FROM AUTHOR]

Published

2024

19. Solar-based Photocatalytic Degradation of Wastewater by Vanadium-doped CaTiO3 Nanoparticles.

Author

Mishra, Shilpa and Sundaram, Baranidharan

Subjects

INDUSTRIAL wastes, SEWAGE disposal plants, WASTEWATER treatment, CHEMICAL oxygen demand, BAND gaps, IRRADIATION

Abstract

Calcium titanate (CaTiO3), a member of the perovskite family, is a multifunctional material with a wide range of uses, including photocatalytic wastewater treatment, electronic devices, lighting and display devices, biomedicine and many more. In this work, for the first time, the CaTiO3 nanoparticles (NPs) doped with different molar (0.2, 0.4, 0.6, and 0.8) percentages of Vanadium (V) were successfully synthesized via a Sol–gel method and used for the photocatalytic treatment of a wide range of wastewater. It is interesting to note that even after doping vanadium, the CaTiO3 crystal structure retained its perovskite structure, and the V-doped CaTiO3 displayed increased solar or visible light absorption with a band gap from 1.96 to 2.34 eV. Studies were conducted using XRD for phase formation, FESEM for morphology, EDX for structural composition, and UV–Vis for band gap. The percentage of Chemical Oxygen Demand (COD) removal was examined under sunlight at various irradiation times ranging from 2 to 8 h with a catalyst dose of 1 g/L and pH of 7.2 to examine the impact of Vanadium doping on the photocatalytic performance of CaTiO3. The percentage of COD removal from sewage treatment plant effluent, textile industry effluent, and landfill leachate was 98%, 94%, and 88% respectively using 0.4 mol% of V-doped CaTiO3. [ABSTRACT FROM AUTHOR]

Published

2024

20. Assessing the impact of leachate irrigation on Medicago sativa (alfalfa) growth, enzymatic responses, and heavy metal accumulation.

Author

Belasri, Lamiaa, Guenaou, Ismail, Hmimid, Fouzia, and Benichou, Samah Ait

Subjects

SUCCINATE dehydrogenase, CHEMICAL oxygen demand, WASTE management, LEACHATE, WATER shortages, BIOCHEMICAL oxygen demand

Abstract

In light of the increasing water scarcity and the need for sustainable waste management, the use of landfill leachate for irrigation has emerged as both a solution and a concern, posing potential risks to soil health and plant vitality. This study examined the multifaceted impacts of leachate irrigation on the soil characteristics, plant growth, and enzymatic activities of Medicago sativa (M. sativa). By exposing alfalfa to different concentrations of leachate, we assessed the influence on heavy metal accumulation, physiological parameters, and enzyme functions. The physicochemical profile of the leachate indicated that the pH was within acceptable limits, but the chemical oxygen demand (COD), biochemical oxygen demand (BOD5), and concentrations of lead (Pb) and aluminum (Al) exceeded regulatory standards. Morphological parameters exhibited dual effects: stimulation at lower leachate doses and inhibition at higher leachate doses. Our findings show that soil acts as a buffer, reducing heavy metal uptake by plants. Enzymatic activities, including catalase, peroxidase, and succinate dehydrogenase, fluctuated significantly at higher leachate concentrations, indicating stress responses. This research underscores the interplay between leachate irrigation, plant physiology, and soil health, emphasizing sustainable management to optimize plant growth and minimize environmental impacts. It also stresses refining leachate application protocols to preserve soil and ecosystem health. [ABSTRACT FROM AUTHOR]

Published

2024

21. Efficient removal of COD, BOD, oil & grease, and turbidity from oil-field produced water via electrocoagulation treatment.

Author

Katare, Aviti and Saha, Prabirkumar

Subjects

BIOCHEMICAL oxygen demand, CHEMICAL oxygen demand, OIL field brines, ALUMINUM hydroxide, MAINTENANCE costs

Abstract

The simple design, compactness, simultaneous treatment of multiple contaminants, absence of chemical usage, minimal sludge formation (reducing secondary pollution), low maintenance cost, and versatility to operate in both batch and continuous modes make electrocoagulation (EC) a promising choice for treating various types of industrial wastewater. In this study, EC was employed in batch mode to treat produced water obtained from an oil drilling site, to reuse it for injection purposes in the reservoir. Produced water typically contains high levels of total dissolved solids (TDS), turbidity, chemical oxygen demand (COD), biological oxygen demand (BOD), and oil & grease (O&G) contaminants. High-performing aluminum (Al) electrodes were chosen due to their stability, conductivity, and, most significantly, their high capacity for generating aluminum hydroxide ([Al(OH)₃]ₙ) flocs, which serve as carriers for contaminant capture. This compound has demonstrated remarkable effectiveness in trapping the aforementioned contaminants from produced water under various operating conditions, including the number of electrodes, supplied current, and electrode configuration (bipolar and monopolar). The impact of several factors, including the number of electrodes (varying from 4 to 8), current density (varying as 16, 79, 158 A/m2), and electrode configuration (bipolar and monopolar), was studied at room temperature and 250 rpm agitation speed. Initial turbidity, COD, BOD, and O&G concentrations were measured at 38 NTU, 700.7 ppm, 120 ppm, and 32.8 ppm, respectively. The EC treatment exhibited removal efficiencies of 51% for TDS, 85% for turbidity, 78% for COD, 80% for BOD, and 85% for O&G using a monopolar configuration with 8 electrodes, and 59% for TDS, 90% for turbidity, 85% for COD, 84% for BOD, and 86% for O&G using a bipolar configuration with eight electrodes. Additionally, cost estimation, considering electrode dissolution rate and power requirements, was conducted for the operation of both configurations. [ABSTRACT FROM AUTHOR]

Published

2024

22. Biohydrogen production from co-substrates through dark fermentation by bacterial consortium.

Author

Mumtha, Chelladurai and Mahalingam, Pambayan Ulagan

Subjects

*SUSTAINABILITY, *INTERSTITIAL hydrogen generation, *CHEMICAL oxygen demand, *CLEAN energy, *SURFACE cracks

Abstract

Hydrogen is a clean energy carrier that can be used as fuel for fuel cells. Dark fermentative biohydrogen production with other waste biomass needs to be explored as an alternative for sustainable biohydrogen production in future. In this study, lab-scale bioreactor were carried out to produce biohydrogen from co-substrates using bacterial consortium at 37 ℃. For the experimental setup, a 1-L-working-volume reactor was used for biohydrogen production by bacterial monocultures and consortium on co-substrates. A batch experiment was performed at 37 °C with an initial pH of 7.0 and a mixing ratio of 600:300 between dairy whey and sugarcane bagasse. Total solids (TS), volatile solids (VS), total chemical oxygen demand (TCOD), soluble chemical oxygen demand (SCOD), and hydrogen production rate (HPR) were determined from co-substrates during the dark fermentation process. Morphologic changes of biohydrogen producing bacteria binds on co-substrates after the fermentation process were determined using SEM imaging. The bacteria can degrade the substrate when they attach to it causing hole formation and cracked the surface area. The level of biohydrogen production by bacterial consortium was observed and the results revealed a hydrogen production rate of 35.9 mL H2/L/h. In fermentative H2 production, it is quite similar to that of most H2-producing bacteria previously studied, especially that of the bacterial consortium, and this indicates that the attempt to find an outstanding bacterial strain for fermentative H2 production might be very difficult if not impossible. [ABSTRACT FROM AUTHOR]

Published

2024

23. Study on the enhancement of low carbon-to-nitrogen ratio urban wastewater pollutant removal efficiency by adding sulfur electron acceptors.

Author

Luo, Erming, Ouyang, Jia, Zhang, Xinxin, Lu, Qian, Wei, Dong, Wang, Yongcheng, Cha, Zhengjiong, Ye, Chengwei, Li, Chun ying, and Wei, Li

Subjects

*NITROGEN removal (Sewage purification), *SEWAGE purification, *SEWAGE disposal plants, *ELECTROPHILES, *CHEMICAL oxygen demand, *DENITRIFICATION, *DESULFURIZATION

Abstract

The effective elimination of nitrogen and phosphorus in urban sewage treatment was always hindered by the deficiency of organic carbon in the low C/N ratio wastewater. To overcome this organic-dependent barrier and investigate community changes after sulfur electron addition. In this study, we conducted a simulated urban wastewater treatment plant (WWTP) bioreactor by using sodium sulfate as an electron acceptor to explore the removal efficiency of characteristic pollutants before and after the addition of sulfur electron acceptor. In the actual operation of 90 days, the removal rate of sulfur electrons' chemical oxygen demand (COD), ammonia nitrogen, and total phosphorus (TP) with sulfur electrons increased to 94.0%, 92.1% and 74%, respectively, compared with before the addition of sulfur electron acceptor. Compared with no added sulfur(phase I), the reactor after adding sulfur electron acceptor(phase II) was demonstrated more robust in nitrogen removal in the case of low C/N influent. the effluent ammonia nitrogen concentration of the aerobic reactor in Pahse II was kept lower than 1.844 mg N / L after day 40 and the overall concentration of total phosphorus in phase II (0.35 mg P/L) was lower than that of phase I(0.76 mg P/L). The microbial community analysis indicates that Rhodanobacter, Bacteroidetes, and Thiobacillus, which were the predominant bacteria in the reactor, may play a crucial role in inorganic nitrogen removal, complex organic degradation, and autotrophic denitrification under the stress of low carbon and nitrogen ratios. This leads to the formation of a distinctive microbial community structure influenced by the sulfur electron receptor and its composition. This study contributes to further development of urban low-carbon-nitrogen ratio wastewater efficient and low-cost wastewater treatment technology. [ABSTRACT FROM AUTHOR]

Published

2024

24. Advancing physical, dielectric, and solar photocatalytic efficiency with novel Ni0.95Cu0.03M0.02O (M = Co, Mo) semiconductors.

Author

Massoudi, Imen and Rebey, Ahmed

Subjects

*X-ray photoelectron spectra, *COPPER, *CHEMICAL oxygen demand, *VISIBLE spectra, *ORGANIC compounds, *METHYLENE blue

Abstract

Cu/Mo codoped NiO semiconductors exhibited a visible light efficient photo-removal performance for diclofenac sodium and methylene blue waste. A simple and low-cost methodology was used to synthesize NiO, Ni0.95Cu0.03Co0.02O, and Ni0.95Cu0.03Mo0.02O nanocatalysts. The crystal structure verified the formation of a cubic NiO single phase. The scanning electron microscopy (SEM) micrographs of all samples have shown a homogenous spherical particle distribution. The harvesting of visible light from NiO semiconductors was significantly enhanced after the addition of Cu/Co and Cu/Mo ions. The X-ray photoelectron spectra confirmed that Cu dopant has a +2-oxidation state while Mo dopant has +3 and +4 as mixed oxidation states. Ni0.95Cu0.03Co0.02O and Ni0.95Cu0.03Mo0.02O have shown high dielectric constant values at low frequencies. For purification of wastewater, the visible light photocatalytic efficiencies of Cu/Mo codoped NiO catalyst for the removal of 20 mg/L methylene blue (MB) and 20 mg/L diclofenac sodium (DS) were 98 and 95% after 50 min, respectively. The MB and DS molecules were converted to CO2 and H2O as confirmed by total organic carbon and chemical oxygen demand analyses. Besides, this nanocatalyst showed a high reusability for MB and DS pollutants until four cycles. [ABSTRACT FROM AUTHOR]

Published

2024

25. Analysis on the relationship between coastal tourism and marine pollution: an empirical analysis of China's 11 coastal regions.

Author

Xina Ji and Xingong Ding

Subjects

TOURISM impact, CHEMICAL oxygen demand, POLLUTANTS, LEAST squares, ECONOMIC expansion, MARINE pollution

Abstract

Introduction: Coastal tourism has become an important pillar of economic growth in China's coastal regions, yet no quantitative research has analyzed the relationship between coastal tourism and marine pollution. Methods: This study, within a multivariate framework, comprehensively examines the impact of coastal tourism on marine pollution by employing various econometric techniques and focusing on four different types of marine pollutant discharges: chemical oxygen demand (COD), petroleum (PET), ammonia nitrogen (NHN), and total phosphorus (TP). Results and discussion: Panel cointegration tests confirm a long-term relationship between coastal tourism and these four types of marine pollutant discharges. In the long run, coastal tourism has a significantly negative impact on COD, NHN, and TP. The results of Pooled Mean Group (PMG), Fully Modified Ordinary Least Squares (FMOLS), and Dynamic Ordinary Least Squares (DOLS) estimators show that for every 1% increase in coastal tourism revenue (TOUR), COD decreases by 0.734%, 0.536%, and 0.952% respectively; NHN decreases by 0.746%, 0.340%, and 1.633%; and TP decreases by 5.169%, 0.899%, and 0.334% respectively. However, the impact of coastal tourism on PET is not significant. The Dumitrescu-Hurlin (D-H) panel causality test results indicate different causality patterns between coastal tourism and various marine pollutant discharges. Specifically, there is a bidirectional causality between coastal tourism and COD, NHN, and a unidirectional causality between coastal tourism and PET, TP. Moreover, heterogeneity analysis reveals that coastal tourism does not significantly reduce all marine pollutant discharges in low-and middleincome coastal regions. Furthermore, compared to the central and southern coastal regions, the coastal tourism of northern regions has not significantly reduced marine pollution. This study can provide policymakers with references for developing coastal tourism and reducing marine pollutant discharges. [ABSTRACT FROM AUTHOR]

Published

2024

26. Redox-switchable microemulsions with efficient phase separation and surfactant recycling.

Author

Wang, Shuyu, Xu, Yanjie, Fang, Yinjun, and Liu, Xuefeng

Subjects

*PHASE separation, *REVERSIBLE phase transitions, *SURFACE active agents, *MICROEMULSIONS, *NUCLEAR magnetic resonance, *CHEMICAL oxygen demand, *BUTANOL

Abstract

[Display omitted] Switchable microemulsions (MEs) are those capable of adaptively responding to the action of internal or external stimuli. For redox-switchable MEs to obtain high-efficiency phase separation and surfactant recycling, it may be one of the keys to adequately turn off the interfacial activity of surfactants and reduce the solubility of the closed surfactants in the oil phase. Monophasic MEs consisting 11-butylselanyl-undecyl sulfate sodium (C 4 SeC 11 SO 4 Na), n -butanol, n -octane, and water were fabricated using the pseudo-ternary phase diagram method. Their structural features and droplets size were characterized by conductivity, dynamic light scattering (DLS) and cryogenic transmission electron microscopy (cryo-TEM), respectively. The redox response of MEs was studied using a combination of visual observations and DLS, cryo-TEM, nuclear magnetic resonance (NMR) and thin-layer tomography. The efficient recycling of C 4 SeC 11 SO 4 Na from a well-emulsified eluent is conceptually demonstrated. The reversible transition between C 4 SeC 11 SO 4 Na and C 4 SeOC 11 SO 4 Na is achieved under the alternating action of H 2 O 2 and N 2 H 4 , by which C 4 SeC 11 SO 4 Na-based monophasic MEs are able to efficiently demulsify and regenerate, respectively, regardless of their type. After H 2 O 2 -induced demulsification of the MEs, C 4 SeOC 11 SO 4 Na can be efficiently recycled with the water phase. We hope that such a redox-switching method may benefit some technological applications. For example, it offers exciting possibilities for simultaneous recycling C 4 SeC 11 SO 4 Na and removal of oil from a well-emulsified eluent. Around 97.1 ± 0.3 % of C 4 SeC 11 SO 4 Na could be recycled over five cycles with no apparent loss. After a simple and conventional treatment with anion-exchange resin and active carbon, the total organic carbon and chemical oxygen demand of the waste water were 17.4 ± 2.8 and 26.2 ± 1.4 mg/L, respectively. [ABSTRACT FROM AUTHOR]

Published

2024

27. Evaluation of Integrated Anaerobic/Aerobic Conditions for Treating Dye-Rich Synthetic and Real Textile Wastewater Using a Soda Lake Derived Alkaliphilic Microbial Consortia.

Author

Aragaw, Tadele Assefa, Suarez, Carolina, Paul, Catherine J., and Simachew, Addis

Subjects

INDUSTRIAL wastes, SYNTHETIC textiles, DEGRADATION of textiles, CHEMICAL reactors, TEXTILE chemicals, CHEMICAL oxygen demand

Abstract

Textile industry wastewater (WW) has intense color, high chemical oxygen demand (COD), pH, and salinity, making it challenging for conventional treatment. Soda lakes, with high alkalinity and salinity, host diverse microbes capable of textile dye degradation. This study evaluated anaerobic/aerobic reactors using alkaliphilic microbial consortia from Lake Chitu, an Ethiopian soda lake, for treating synthetic and real textile WW. The experimental setup consisted of a first-stage anaerobic reactor followed by a second-stage aerobic reactor, operating continuously with a predetermined flow rate and hydraulic residence time. After evaluating synthetic WW, real textile WW was collected in two batches (rounds I and II). The treatment setup removed 99% of the dye color for synthetic WW, 98% for round I, and 96% for round II. COD removal was 87% for synthetic WW, 86% for round I, and 93.37% for round II. TKN removal reached 90% for synthetic WW, 91% for round I, and 96% for round II at a steady state. Residual COD and TKN values met the final effluent discharge standards. GC–MS and IR analyses revealed that dyes were broken down into intermediate organic compounds under anaerobic conditions and further degraded into smaller molecules under aerobic conditions. This integrated reactor approach effectively removes dyes and enhances COD and TKN removal. The study's novelty lies in evaluating both synthetic and real textile WW using integrated reactors under alkaline conditions in a continuous process, inoculating alkaliphilic consortia, without pre-enrichment or external nutrient addition to real WW. The study provides insights into the effectiveness of alkaliphilic microbial consortia derived from soda lakes for treating textile WW using integrated reactor conditions. Reactor microbiome characterization is needed to further explore microbial diversity and community structure. [ABSTRACT FROM AUTHOR]

Published

2024

28. Effects of In-Season Velocity-Based vs. Traditional Resistance Training in Elite Youth Male Soccer Players.

Author

Sekulović, Veselin, Jezdimirović-Stojanović, Tatjana, Andrić, Nikola, Elizondo-Donado, Andoni, Martin, Diego, Mikić, Mladen, and Stojanović, Marko D. M.

Subjects

RESISTANCE training, ELITE athletes, STRENGTH training, VERTICAL jump, SOCCER players, CHEMICAL oxygen demand

Abstract

The objectives of this study were to compare the effects of two in-season velocity loss training methods (VBT) on performance outcomes and to evaluate the effects of velocity-based training compared to traditional resistance training (TRT) on performance outcomes in young elite soccer players. VBT utilized the same relative load but varied in the extent of velocity loss during the set: 15% (VL15%) and 30% (VL30%). Thirty-four players were recruited and randomly distributed into three groups: the VL15% group (n = 12; age = 18.50 ± 0.67 years; stature = 183.41 ± 4.25 cm; body mass = 75.08 ± 5.57 kg), the VL30% group (n = 11; age = 17.91 ± 0.60 years; stature = 181.21 ± 6.56 cm, body mass = 73.58 ± 6.22 kg), and the traditional strength training group TRT (n = 11; age = 18.14 ± 0.74 years; stature = 182.17 ± 5.52 cm; body mass = 74.86 ± 6.68 kg). Alongside regular soccer sessions and matches, the groups underwent a four-week (2 sesions per week) resistance training intervention with back squats involved. Changes in leg strength (SQ1RM), 20 m sprint time (SPR 20 m), countermovement jump height (CMJ), reactive strength index (RSI), and change of direction (COD) from before and after were evaluated using a 3 × 2 ANOVA. While no significant interaction was found for SQ1RM and SPR20, all of the groups showed significant pre to post improvements. Significant interactions were observed for CMJ (F = 38.24, p = 0.000), RSI (F = 8.33; p = 0.001), and change of direction agility test (COD) (F = 3.64; p = 0.038), with a post hoc analysis showing differences between the VL15 (6.0%) and TRT (1.7%) groups (p = 0.034); VL15 (12.2%) and VL30 (3.2%) groups (p = 0.004); VL15 and TRT (0.4%) (p = 0.018); VL15 (2.4%) and VL30 (1.5%) (p = 0.049); and between the VL15 and TRT (0.4%) groups (p = 0.015). Four weeks of VL15% training during the season induced similar strength increases to VL30% and TRT, superior improvements in RSI and COD compared to VL30%, and superior improvements in CMJ, RSI, and COD tests compared to TRT. Thus, incorporating the VL15% training method may be recommended to improve power-related performance metrics in elite young soccer players. [ABSTRACT FROM AUTHOR]

Published

2024

29. Assessment of amoxicillin (AMX) removal from aqueous medium through Rhapis-based bioretention system.

Author

Muduli, Monali, Gohil, Harshdeepsinh, Satasiya, Gopi, Ansari, Nagma, Nair, Athira, and Ray, Sanak

Subjects

PRINCIPAL components analysis, ORNAMENTAL plants, RF values (Chromatography), PLANT growth, PLANT development, CONSTRUCTED wetlands, CHEMICAL oxygen demand

Abstract

Antibiotics can be effectively removed from wastewater using constructed wetlands (C.W.s). However, little is known about using attractive garden plants in C.W.s to eliminate antibiotics. Thus, the current study aims to treat amoxicillin (AMX)-contaminated wastewater through a Rhapis excelsa-based bioretention system (BS). The investigation was done at 15 days hydraulic retention time (HRT) under two conditions: set-1, varied AMX 5 to 25 ppm with constant NPK (nitrogen, phosphorus, potassium) source; and set-2, varied NPK sources with constant AMX (25 ppm). During the study, it was observed that in the set-1 condition with increasing AMX concentration, the removal of AMX through BS decreased; however, in the set-2 experiment, with enhancing NPK source, the performance of the BS treating 25-ppm AMX-contaminated wastewater increased. AMX removal of 2.3%, 66.3%, 60.6%, 52.2%, 46.7%, and 44.9% was achieved for control, BS-1, BS-2, BS-3, BS-4, and BS-5, respectively, during set-1 experiment. However, in the set-2 experiment, 23.4% (control), 43.3% (BS-1), 60.3% (BS-2), 75.9% (BS-3), 88.8% (BS-4), and 99% (BS-5) AMX removal were achieved. Removing pollutants like AMX, COD, PO43−-P, NO3−-N, and NH4+-N followed first-order kinetics. A positive correlation of COD with AMX was observed through principal component analysis and correlation matrix. The microbial community study was also covered to prioritize the role of microbes in treating AMX through BSs. The AMX treatment through Rhapis excelsa-based BS supported plant growth and development with increasing chlorophyll content, fresh weight, and C, H, N value. [ABSTRACT FROM AUTHOR]

Published

2024

30. A comprehensive study on the effects of electrocoagulation integrated in a membrane bioreactor treating sunflower oil refinery wastewater on treatment performance, biological properties, and fouling behavior.

Author

Sharghi, Elham Abdollahzadeh, Miri, Marjan, Davarpanah, Leila, and Faridizad, Ghazale

Subjects

SEWAGE purification, SUNFLOWER seed oil, CHEMICAL oxygen demand, PARTICLE size distribution, MICROBIAL products

Abstract

This study evaluated the effects of electrocoagulation integrated in a laboratory-scale membrane bioreactor (MBR), namely EC-MBR, on the treatment performance, activated sludge morphological characterization, and membrane fouling of MBR treating actual sunflower oil refinery wastewater. The EC-MBR system exhibited significantly higher chemical oxygen demand (COD) and oil and grease (O&G) removal efficiency compared to the MBR system. Additionally, both systems achieved excellent turbidity removal, with a percentage above 99%. The membrane fouling rate was higher in the EC-MBR system compared to the MBR system. Despite the decrease in the soluble microbial product (SMP) and extracellular polymeric substance (EPS) concentration in the EC-MBR system, especially their protein fraction, the significant increase in MLSS and carbohydrates/protein ratio, and the decrease in the mixed liquor and the cake layer particles size were the main membrane fouling factors. The membrane fouling resistance distribution showed that the EC-MBR system had a higher percentage of pore blocking resistance compared to the MBR. FTIR analysis identified a greater proportion of carbohydrate compounds in the cake layer of the EC-MBR system. SEM images revealed dense microbial clusters, mainly rod- and oval-shaped bacteria, in the EC-MBR system. Furthermore, EDX analysis detected elements such as Ca, K, O, Al, and P in both systems, with the EC-MBR system showing a higher Al content. The EC-MBR system showed low energy consumption (0.431 kWh m−3) and total operating costs ($0.90 m−3), showcasing its effectiveness and affordability for sustainable wastewater management. [ABSTRACT FROM AUTHOR]

Published

2024

31. Pollution control and biodiesel production with microalgae: new perspectives on the use of flat panel photobioreactors regarding variation in volume application rate.

Author

de Mello Mattos, Cecília, dos Santos, Mônica Silva, Santana, Jacob, de Carvalho, Daniel Fonseca, Massache, Assamo, Zonta, Everaldo, Boas, Renata Vilas, Lucchetti, Leonardo, Mendes, Marisa, and de Mendonça, Henrique Vieira

Subjects

FATTY acid analysis, CETANE number, CHEMICAL oxygen demand, BIOREMEDIATION, CARBON sequestration

Abstract

In the present study, the microalga Arthrospira platensis DHR 20 was cultivated in vertical flat-plate photobioreactors (FPBRs) to bioremediate anaerobically digested cattle wastewater (ACWW) and used as a growth substrate. The final objective was to evaluate the properties of the oil extracted from this biomass to determine its potential for biodiesel production. The process was divided into five phases, varying the volume of the applied substrate: 1 L (Phase I), 5 L (Phase II), 10 L (Phase III), 15 L (Phase IV), and 20 L (Phase V). Dry biomass reached a maximum of 5.7 g L−1, and productivity peaked at 0.74 g L−1d−1. The highest rate of CO2 biofixation was 1213.5 mg L−1 day−1, showing good potential for purifying the air. The highest specific maximum growth rate (μmax) and the shortest doubling time (Dt) were found during Phase I. The removal of pollutants and nutrients during the experimental phases ranged from 65.8% to 87.1% for chemical oxygen demand (COD), 82.2% to 85.8% for total organic carbon (TOC), 91% to 99% for phosphate (PO43−), 62.5% to 93% for nitrate (NO3−), 90.4% to 99.7% for ammoniacal nitrogen (NH4+), and 86.5% to 98.5% for total nitrogen (TN). The highest lipid production recorded was 0.172 g L−1 day−1. The average cetane number recorded in Phase IV of 51 suggests that the fuel will ignite efficiently and consistently, providing smooth operation and potentially reducing pollutant emissions. The analysis of fatty acids revealed that the produced biodiesel has the potential to be used as an additive for other low-explosive biocombustibles, representing an innovative and sustainable approach that simultaneously offers bioremediation and carbon sequestration. [ABSTRACT FROM AUTHOR]

Published

2024

32. Physiological and biomolecular interventions in the bio-decolorization of Methylene blue dye by <italic>Salvinia molesta</italic> D. Mitch.

Author

Dolui, Debabrata, Das, Abir, Hasanuzzaman, Mirza, and Adak, Malay Kumar

Subjects

*AQUATIC weeds, *INDUSTRIAL wastes, *CHEMICAL oxygen demand, *AZO dyes, *BASIC dyes

Abstract

Abstract\nNOVELTY STATEMENTMethylene blue, a cationic dye as a pollutant is discharged from industrial effluent into aquatic bodies. The dye is biomagnified through the food chain and is detrimental to the sustainability of aquatic flora. Despite of number of physico-chemical techniques of dye removal, the use of aquatic flora for bio-adsorption is encouraged. Thus, we used Salvinia molesta D. Mitch in bio-reduction of methylene blue on concentrations of 0, 10, 20, and 30 mg L−1 through 5 days with biosorption kinetics. The dye removal was concentration-dependent, maximized at 2 days with 30 mg L−1 which altered the relative growth rate (44%) of plants. Biosorption recorded 71% capacity at optimum pH (8.0), 24 h reducing major bond energies of amide, hydroxyl groups, etc. Bioaccumulation of dye changed potassium content (446%) under maximum dye concentration modifying tissues for dye sequestration. Reactive oxygen species were altered on dye reduction by oxidase (33%) with redox homeostasis by enzymes. Plants altered the metabolism with over accumulation of polyamines (51%), abscisic acids (448%), and phosphoenolpyruvate carboxylase (83%) on dye reduction. Thus, this study is rationalized with a sustainable approach where aquatic ecosystems can be decontaminated from dye toxicity with the exercise of bioresources like Salvinia molesta D. Mitch as herein.Azo dyes as industrial effluents are more hazardous with their high solubility in water causing inhibition of life processes in aquatic ecosystem. Methylene blue as a dye, in the aquatic environment deteriorates the ecosystem by increasing a chemical oxygen demand, impairing light harnessing mechanism, inhibiting growth of microflora, recalcitrance, bioaccumulation, mutagenicity of the whole environment. Aquatic weed like Salvinia molesta D. Mitch is evident as an effective bio-adsorbent, bio-decolorization, finally dye removing material to reduce water pollution as an alternative strategy for environmental remediation. [ABSTRACT FROM AUTHOR]

Published

2024

33. Production of α-ketoisovalerate with whey powder by systemic metabolic engineering of Klebsiella oxytoca.

Author

Sun, Weikang, Wang, Shuo, Tan, Xiaoxu, Guo, Leilei, Liu, Wei, Tian, Wenjia, Zhang, Hui, Jiang, Tianyi, Meng, Wensi, Liu, Yidong, Kang, Zhaoqi, Lü, Chuanjuan, Gao, Chao, Xu, Ping, and Ma, Cuiqing

Subjects

*BIOCHEMICAL oxygen demand, *CHEMICAL oxygen demand, *KLEBSIELLA oxytoca, *AMINATION, *WHEY, *DECARBOXYLATION

Abstract

Background: Whey, which has high biochemical oxygen demand and chemical oxygen demand, is mass-produced as a major by-product of the dairying industry. Microbial fermentation using whey as the carbon source may convert this potential pollutant into value-added products. This study investigated the potential of using whey powder to produce α-ketoisovalerate, an important platform chemical. Results: Klebsiella oxytoca VKO-9, an efficient L-valine producing strain belonging to Risk Group 1 organism, was selected for the production of α-ketoisovalerate. The leucine dehydrogenase and branched-chain α-keto acid dehydrogenase, which catalyzed the reductive amination and oxidative decarboxylation of α-ketoisovalerate, respectively, were inactivated to enhance the accumulation of α-ketoisovalerate. The production of α-ketoisovalerate was also improved through overexpressing α-acetolactate synthase responsible for pyruvate polymerization and mutant acetohydroxyacid isomeroreductase related to α-acetolactate reduction. The obtained strain K. oxytoca KIV-7 produced 37.3 g/L of α-ketoisovalerate from lactose, the major utilizable carbohydrate in whey. In addition, K. oxytoca KIV-7 also produced α-ketoisovalerate from whey powder with a concentration of 40.7 g/L and a yield of 0.418 g/g. Conclusion: The process introduced in this study enabled efficient α-ketoisovalerate production from low-cost substrate whey powder. Since the key genes for α-ketoisovalerate generation were integrated in genome of K. oxytoca KIV-7 and constitutively expressed, this strain is promising in stable α-ketoisovalerate fermentation and can be used as a chassis strain for α-ketoisovalerate derivatives production. [ABSTRACT FROM AUTHOR]

Published

2024

34. Agricultural waste–based biochars for sustainable removal of heavy metals from stabilized landfill leachate.

Author

Soudani, Amina, Youcef, Leila, Chebbi, Meriem, Bulgariu, Laura, and Patel, Nageshvar

Subjects

BIOCHEMICAL oxygen demand, CHEMICAL oxygen demand, HEAVY metals, COPPER, METALS removal (Sewage purification)

Abstract

In this work, biochars were used as adsorbents to remove Cu, Cd, and Zn ions in a real stabilized leachate from a controlled landfill. Oak fruit shells biochar (OFSBC) and date palm fibers biochar (DPFBC) were obtained by pyrolysis of oak fruit shells and date palm fibers at 700 °C and 400 °C, respectively. OFSBC and DPFBC showed well-developed structures and high specific surface areas (520.16 m2/g and 470.46 m2/g, respectively). Equilibrium adsorption of heavy metal ions on DPFBC and OFSBC occurred after 4 h and 2 h of stirring. The removal efficiencies of Cu, Cd, and Zn ions were 97.01%, 94.40%, and 80.59% with DPFBC and 90.10%, 88.33%, and 76.16% using OFSBC, respectively. The Avrami fractional order model was appropriate for describing kinetic adsorption. Increasing the dose of adsorbent improves heavy metal ion retention. Thermodynamic tests have proven the spontaneous and endothermic adsorption of these heavy metals. The electrostatic attraction, ion exchange, complexation, metal-π bending, and surface precipitation and pore filling were regarded as the most predominant heavy metal retention mechanisms from the landfill leachate onto the biochar surface. Separately, the DPFBC showed the best performance than OFSBC regarding the improvement of leachate quality. Chemical oxygen demand (COD), biological oxygen demand (BOD5), ammoniacal nitrogen (NH3-N), and phosphorus (P) were respectively removed at an efficiency of 53.57%, 29.17%, 36.07%, and 37.5%, respectively. Thus, the results allow highlighting that the adsorption on DPFBC and OFSBC can be an effective alternative in the practice of landfill leachate treatment. [ABSTRACT FROM AUTHOR]

Published

2024

35. Ecological indicators of water quality and marshland impact area (MARia) index of Ligawasan Marsh: a critically important wetland in the Southern Mindanao, Philippines.

Author

Tanalgo, Krizler Cejuela, Manampan-Rubio, Meriam, Alvaro-Ele, Renee Jane, Hilario-Husain, Bona Abigail, Murray, Sedra A., Delos Reyes, Jamaica L., Pangato, Nasrodin M., Magkidong, Noril S., Angcaco, Kayle Lou D., Catulos, Angelie J., Dimacaling, Ace D., Ruiz, Julius O., Abdulkasan, Rallyessa Mohann A., Murray-Buday, Melanie, Lidasan, Asraf K., Dela Cruz, Kier Celestial., Respicio, Jeaneth Magelen V., Abdullah, Sumaira S., and Agduma, Angelo Rellama

Subjects

AQUATIC ecology, BIOINDICATORS, BIOCHEMICAL oxygen demand, CHEMICAL oxygen demand, FRESHWATER ecology

Abstract

Wetland ecosystems are vital for both biodiversity and communities that depend on them. The Ligawasan Marsh in the southern part of the Philippines is one of the most threatened wetlands in the country. Apart from increasing anthropogenic development, wetlands have faced warfare-driven threats that have hindered research and conservation efforts in the area for many decades. Our study is the first to investigate the patterns of physicochemical parameters, patterns of land use cover, and the relationship between land use change and marshland environmental status. We also developed the Marshland Impact Area (MARia) index to assess the potential impact contributions of the surrounding towns. We found a strong negative correlation between dissolved oxygen (DO) and indicators of pollution such as biochemical oxygen demand (BOD), chemical oxygen demand (COD), and heavy metals. Interestingly, we observed elevated levels of phosphate and mercury at all sampling sites in the Ligawasan Marsh. Our landscape-level modelling showed that these elevated levels are associated with expanding croplands and urbanisation surrounding the marsh. We found that the potential impact contribution of cropland and urbanisation from surrounding towns of the Ligawasan Marsh varied significantly, suggesting the importance of implementing local policies to reduce land use change impacts. With the current yet remaims limited knowledge and beyond safe pollution levels in the Ligawasan Marsh, it is crucial to implement collaborative and science-based governance to integrate conservation initiatives with the priorities of global targets, such as the Kunming-Montreal Global Biodiversity Framework, for a comprehensive and sustainable approach to Ligawasan Marsh conservation. [ABSTRACT FROM AUTHOR]

Published

2024

36. Optimization of Microbial Fuel Cell Operational Parameters for the Treatment of Brewery Sludge.

Author

Gebrehiwot, Hagos Mebrahtu and Kassahun, Shimelis Kebede

Subjects

*BIOCHEMICAL oxygen demand, *MICROBIAL fuel cells, *SEWAGE sludge, *CHEMICAL oxygen demand, *RESPONSE surfaces (Statistics)

Abstract

This study investigates the potential of a salt bridge‐mediated microbial fuel cell (MFC) for power generation and wastewater sludge treatment in breweries. Unlike traditional "one‐parameter‐at‐a‐time" methodologies, this study uses a three‐variable Box–Behnken design response surface methodology to optimize critical MFC operational parameters. The effects of parameters such as solution pH, salt bridge molarity, and temperature were studied in the range of 4 to 10, 1 to 5 M, and 20 to 45 g L−1. The optimum operating parameters were found to be solution pH of 5.853, salt bridge molarity of 3.343 M, and temperature of 32.5 °C for chemical oxygen demand and biological oxygen demand removal efficiencies of 92.485 % and 88.51 %, respectively. Temperature was found to be the most significant factor affecting the reactor's performance. [ABSTRACT FROM AUTHOR]

Published

2024

37. Treatment of textile wastewater in combined granular activated carbon-membrane bioreactor (GAC-MBR).

Author

TECİRLİ, Emine Şule, AKGÜN, Kadir, ÇAĞLAK, Abdulkadir, SARI ERKAN, Hanife, and ONKAL ENGİN, Güleda

Subjects

*INDUSTRIAL wastes, *SEWAGE, *CHEMICAL oxygen demand, *WASTEWATER treatment, *ACTIVATED carbon

Abstract

In recent years, the membrane bioreactor (MBR) process has been seen as a promising technology for the treatment of both municipal and industrial wastewater, including textile wastewater which has the potential to generate high levels of pollution in the receiving environment. However, membrane fouling during MBR operation is seen as one of the most important drawbacks due to the reduction of membrane flux. In this study, granular activated carbon MBR (GAC-MBR) technology was investigated to treat real textile wastewater. In this context, conventional MBR (R1) and GAC-MBR (R2) with GAC (300 mg) were operated for 48 days. A flat-plate ceramic membrane module was used in both reactors. The chemical oxygen demand (COD) and color removal efficiencies were found to be 87±3% and 73±7% in conventional MBR, whereas these pollutant removal efficiencies were determined as 89±6.4% and 78±4.8%, respectively, in the GAC-MBR process. According to the results obtained, while conventional MBR required physical cleaning every other day, GAC-MBR did not require any cleaning after the addition of GAC. It was also observed that GAC had no direct effects on the excretion of soluble and loosely-bound or tightly-bound extracellular polymeric substances, however, reduced the transmembrane pressure, capillary suction time, and membrane fouling propensity. [ABSTRACT FROM AUTHOR]

Published

2024

38. Preparation of Co–Ce@RM catalysts for catalytic ozonation of tetracycline.

Author

Sun, Wenquan, Xie, Yiming, Zhang, Ming, Zhou, Jun, and Sun, Yongjun

Subjects

*CHEMICAL oxygen demand, *SCISSION (Chemistry), *CATALYTIC activity, *DOUBLE bonds, *DOPING agents (Chemistry), *REACTIVE oxygen species

Abstract

In this work, a Co–Ce@RM ozone catalyst was developed using red mud (RM), a by‐product of alumina production, as a support material, and its preparation process, catalytic efficiency, and tetracycline (TCN) degradation mechanism were investigated. A comprehensive assessment was carried out using the 3E (environmental, economic, and energy) model. The optimal production conditions for Co–Ce@RM were as follows: The doping ratio of Co and Ce was 1:3, the calcination temperature was 400°C, and the calcination time was 5 h, achieving a maximum removal rate of 87.91% of TCN. The catalyst was characterized using different analytical techniques. Under the conditions of 0.4 L/min ozone aeration rate, with 9% catalyst loading and solution pH 9, the optimal removal rates and chemical oxygen demand by the Co–Ce catalytic ozonation at RM were 94.17% and 75.27%, respectively. Moreover, free radical quenching experiments showed that superoxide radicals (O2−) and singlet oxygen (1O2) were the main active groups responsible for the degradation of TCN. When characterizing the water quality, it was assumed that TCN undergoes degradation pathways such as demethylation, dehydroxylation, double bond cleavage, and ring‐opening reactions under the influence of various active substances. Finally, the 3E evaluation model was deployed to evaluate the Co–Ce@RM catalytic ozonation experiment of TCN wastewater. Practitioner Points: The preparation of Co–Ce@RM provides new ideas for resource utilization of red mud.Catalytic ozonation by Co–Ce@RM can produce 1O2 active oxygen groups.The Co–Ce@RM catalyst can maintain a high catalytic activity after 20 cycles.The degradation pathway of the catalytic ozonation of tetracycline was fully analyzed.Catalytic ozone oxidation processes were evaluated by the "3E" (environmental, economic, and energy) model. [ABSTRACT FROM AUTHOR]

Published

2024

39. An investigation into the performance and perikinetics of Brassica nigra meal in the treatment of real vegetable oil refinery condensate effluent.

Author

Annamalaisamy, Kavithakani and Kumaran, Chithra

Subjects

*MUSTARD, *VEGETABLE oils, *CHEMICAL oxygen demand, *CIRCULAR economy, *PETROLEUM refineries, *FLOCCULANTS

Abstract

In this study, the treatment of vegetable oil refinery plant condensate effluent (VORCE) having high total suspended solids (TSS) and chemical oxygen demand (COD) generated from acid oil unit was focused. The utilization of waste Brassica nigra meal (BNM) as protein flocculant in treating VORCE was explored. The B. nigra meal flocculant (BNMF) exhibited a crystalline nature, with the presence of amino and carboxyl functional groups, rendering it highly efficient (89.69% efficiency) in floc formation. Zeta potential and particle size (−5.6 mV and 240.68 nm, respectively) indicate BNMF's effectiveness in initiating floc formation. The interactive effects of pH, dosage, settling time on COD, and TSS removal were investigated using the Box–Behnken design. At an optimal pH of 6.9 and BNMF dosage of 0.77 g/L, a maximum removal of 85.38% COD and 72.56% TSS was obtained. The perikinetic theory for the coagulation–flocculation followed a second‐order rate reaction with high Kc (0.0001 L/mg min), low settling time (37.04 min), and high collision efficiency (2.703 × 1017), indicating the model's significance in achieving maximum COD and TSS removal. These findings highlight the potential use of BNMF in the treatment of VORCE, leading to circular economy by valorizing waste from mustard oil extraction and zero discharge. Practitioner points: Valorization of waste Brassica nigra meal (BNM) as a potent protein flocculantOptimization for vegetable oil refinery condensate effluent (VORCE) treatment was done.Interactive effects of the process parameters were analyzed using Design expert.Perikinetic theory for VORCE treatment follows second‐order reaction rate with high Kc. [ABSTRACT FROM AUTHOR]

Published

2024

40. Study on the response mechanisms and evolution prediction of groundwater microbial‐toxicological indicators.

Author

Sun, Weichao, Wang, Shuaiwei, Bi, Junbo, Ning, Zhuo, Wang, Jingjing, and Hou, Haibo

Subjects

*GROUNDWATER temperature, *ENVIRONMENTAL quality, *CHEMICAL oxygen demand, *ENVIRONMENTAL indicators, *WATER quality

Abstract

This study aims to investigate the response mechanisms of groundwater microbial‐toxicological indicators, specifically total bacteria count (TBC) and total coliform count (TCC), to water quality indicators and environmental conditions. Using data from a water source in the western plateau of China, a predictive model focusing on TBC and TCC was developed. An orthogonal experimental design was employed to manipulate environmental conditions such as temperature, pH, and porosity, facilitating laboratory experiments. These experiments measured pH, chemical oxygen demand (COD), oxidation–reduction potential (ORP), TBC, and TCC at varying depths and environmental conditions. Principal component analysis elucidated the mechanisms by which water quality indicators and environmental conditions affect groundwater microbial–toxicological indicators. A prediction model for these indicators in plateau regions was established based on a backpropagation neural network (BP‐NN), using TBC and TCC as target variables and the newly extracted principal components as influencing factors. The results demonstrate that environmental conditions and water quality indicators primarily influence the evolution of groundwater microbial–toxicological indicators by altering the ionic charge quantities, redox conditions, and temperature of the groundwater. The predictive model for groundwater microbial–toxicological indicators shows trends consistent with experimental outcomes, with an average relative error of less than 15%, meeting engineering requirements. Practitioner points: The values of total bacteria count (TBC) and total coliform count (TCC) under different conditions were obtained by column experiments.The influence mechanism of environmental conditions and groundwater indicators on TBC and TCC was elaborated by principal component analysis.TBC and TCC prediction models were established through the investigation of water sources in a plateau area and laboratory experiments. [ABSTRACT FROM AUTHOR]

Published

2024

41. Effects of Polyethylene Terephthalate Microplastics on Anaerobic Mono-Digestion and Co-Digestion of Fecal Sludge from Septic Tank.

Author

Ma, Tingting, Liu, Nana, Li, Yuxuan, Ye, Ziwang, Chen, Zhengxian, Cheng, Shikun, Campos, Luiza C., and Li, Zifu

Subjects

*SEPTIC tanks, *SEWAGE sludge digestion, *CHEMICAL oxygen demand, *POLYETHYLENE terephthalate, *ANAEROBIC digestion, *BIOCHEMICAL oxygen demand

Abstract

Anaerobic digestion (AD) is one of the most significant processes for treating fecal sludge. However, a substantial amount of microplastics (MPs) have been identified in septic tanks, and it remains unclear whether they impact the resource treatment of feces. To investigate this, polyethylene terephthalate (PET) was used as an indicator of MPs to study their effect on the anaerobic digestion of fecal sludge (FS). Two digestion systems were developed: FS mono-digestion and FS co-digestion with anaerobic granular sludge. The results indicated that the effects of PET varied between the two systems. PET inhibited volatile fatty acid synthesis in both systems, but the inhibition period differed. During mono-digestion, PET slightly increased gas and methane production, in contrast to the co-digestion system, where PET reduced methane production by 75.18%. Furthermore, in the mono-digestion system, PET increased soluble chemical oxygen demand and ammonia nitrogen concentrations while blocking phosphorus release, whereas the co-digestion system showed the opposite effects. Ultimately, the choice of digestion method is crucial for the resource utilization of septic tank sludge, and the impact of MPs on AD cannot be ignored. [ABSTRACT FROM AUTHOR]

Published

2024

42. Enhanced Photocatalytic Paracetamol Degradation by NiCu-Modified TiO 2 Nanotubes: Mechanistic Insights and Performance Evaluation.

Author

Pinna, Marco, Zava, Martina, Grande, Tommaso, Prina, Veronica, Monticelli, Damiano, Roncoroni, Gianluca, Rampazzi, Laura, Hildebrand, Helga, Altomare, Marco, Schmuki, Patrik, Spanu, Davide, and Recchia, Sandro

Subjects

*SUSTAINABLE chemistry, *EMERGING contaminants, *CHEMICAL oxygen demand, *BIMETALLIC catalysts, *PHOTODEGRADATION, *IRRADIATION

Abstract

Anodic TiO2 nanotube arrays decorated with Ni, Cu, and NiCu alloy thin films were investigated for the first time for the photocatalytic degradation of paracetamol in water solution under UV irradiation. Metallic co-catalysts were deposited on TiO2 nanotubes using magnetron sputtering. The influence of the metal layer composition and thickness on the photocatalytic activity was systematically studied. Photocatalytic experiments showed that only Cu-rich co-catalysts provide enhanced paracetamol degradation rates, whereas Ni-modified photocatalysts exhibit no improvement compared with unmodified TiO2. The best-performing material was obtained by sputtering a 20 nm thick film of 1:1 atomic ratio NiCu alloy: this material exhibits a reaction rate more than doubled compared with pristine TiO2, enabling the complete degradation of 10 mg L−1 of paracetamol in 8 h. The superior performance of NiCu-modified systems over pure Cu-based ones is ascribed to a Ni and Cu synergistic effect. Kinetic tests using selective holes and radical scavengers unveiled, unlike prior findings in the literature, that paracetamol undergoes direct oxidation at the photocatalyst surface via valence band holes. Finally, Chemical Oxygen Demand (COD) tests and High-Resolution Mass Spectrometry (HR-MS) analysis were conducted to assess the degree of mineralization and identify intermediates. In contrast with the existing literature, we demonstrated that the mechanistic pathway involves direct oxidation by valence band holes. [ABSTRACT FROM AUTHOR]

Published

2024

43. Radiolytic Degradation of Ethylene Glycol and Glycerol in Aqueous Solutions.

Author

Kholodkova, E. M., Popova, A. V., Artamonova, K. A., and Ponomarev, A. V.

Subjects

*CHEMICAL oxygen demand, *ABSORBED dose, *AQUEOUS solutions, *IONIZING radiation, *ELECTRON beams

Abstract

The influence of absorbed dose (up to 90 kGy) and the initial concentrations of ethylene glycol and glycerol (from 30 to 250 mg/L) on their degradation in aqueous solutions under a 3-MeV electron beam has been studied. Aeration of the solutions during irradiation decreased the yield of degradation. In the absence of aeration, the observed initial yields of degradation were about 0.23 µmol/J for ethylene glycol and about 0.14 µmol/J for glycerol. Degradation products formed in aqueous solutions are more resistant to ionizing radiation compared to the parent alcohols. A simultaneous reduction in alcohol concentration and chemical oxygen demand (COD) to standard values was achieved in solutions with an initial concentration of 30–40 mg/L at a dose of no higher than 2–3 kGy. [ABSTRACT FROM AUTHOR]

Published

2024

44. Rapid and efficient degradation of tetrahydrofurfuryl alcohol and polyvinyl alcohol in complex organic low-level radioactive wastewater by Fenton oxidation.

Author

Xia, Xue, Li, Weimin, Feng, Haining, Shen, Weiwei, Liu, Chang, Nie, Xiaoqin, and Dong, Faqin

Subjects

*CHEMICAL oxygen demand, *SEWAGE, *ORGANIC compounds, *OXIDATION

Abstract

During the production of UO2 core fuel elements for high-temperature gas-cooled reactors, a complex organic low-level radioactive wastewater (OLLRW) containing large amounts of tetrahydrofurfuryl alcohol (THFA), polyvinyl alcohol (PVA), and other organics is generated. So it's urgent to have a pretreatment method to efficiently degrade the large and small molecular organic matters. Therefore, the Fenton continuous oxidation method developed in this study cleverly utilizes the secondary enhanced oxidation of H2O2. Compared with the conventional advanced oxidation method, the degradation efficiency of organic matter in simulated wastewater by continuous Fenton oxidation can be doubled, reaching 99.5%. The chemical oxygen demand (COD) of real complex uranium-containing OLLRW was reduced from 18,480 to 979.0 mg L−1. After further oxidative degradation of organic compounds in simulated OLLRW, the COD of wastewater can be reduced to 88.9 mg L−1. This method can effectively mitigate the "toxic" effect of organic matter on adsorption process, thus providing a new idea for the pretreatment of complex OLLRW in high-temperature gas-cooled reactors. [ABSTRACT FROM AUTHOR]

Published

2024

45. Assessment of water pollution in a waste storage drainage area (a case study in Eskişehir, Türkiye).

Author

KAYABAŞI, Ali, TOYGAR SAĞIN, Özlem, and GÖKÇEOĞLU, Candan

Subjects

*HEAVY metal toxicology, *BIOCHEMICAL oxygen demand, *ANALYSIS of heavy metals, *WATERSHEDS, *CHEMICAL oxygen demand

Abstract

Before 2016, the Eskişehir city landfill was an irregular landfill. Since then, it has been transformed into a regulated landfill. This study aimed to investigate the presence of pollution in the landfill drainage area. For this purpose, water samples were collected from the landfill drainage area and the Kadirbey Farm Spring, upstream of the landfill area, during the rainy and dry seasons of 2021. Analyses of the heavy metal content, total dissolved soil (TDS), chemical oxygen demand, biochemical oxygen demand, pH, phenol material content, ammonia nitrogen content, and conductivity were conducted on the samples. Electrical resistivity tomography (ERT) measurements were also performed along the stream bed. According to Turkish Soil Water Quality regulations, the TDS concentrations of all the samples, except one, were lower than the limits for class 3 water quality. The conductivity limits were within the acceptable range for class 3 water quality. The pH of the water samples was alkaline. The calculated leachate pollution index values indicated a pollution risk. The heavy metal pollution index values for the water samples were under 100. Additionally, 75% of the samples were in the very pure category according to the heavy metal evaluation index, with the remaining samples classified as slightly affected. According to the ERT measurements, soils with low resistivity near the landfill were notably laterally wider. The conductivity decreased with the increasing distance from the landfill site. Low resistivity zones, such as plumes, were disconnected from each other. The shape and volume of highly contaminated plumes decreased toward BH1. Based on the study outcomes, it is recommended to measure the water pollution parameters at periodic intervals within the landfill drainage area. [ABSTRACT FROM AUTHOR]

Published

2024

46. Synthesis of potash alum from waste aluminum cans for the purification of river water.

Author

Tetteh, Samuel and Mahama, Nuriya

Subjects

*TOTAL suspended solids, *WATER purification, *CHEMICAL oxygen demand, *X-ray powder diffraction, *ALUMINUM cans

Abstract

This study explored the synthesis of potash alum from disposed aluminum cans for water purification. The effect of the labels on the cans on the yield of alum was also investigated as it is economically beneficial for industry. Single crystals of potash alum were obtained and characterized by powder X-ray diffraction (P-XRD) and Fourier transform infrared (FTIR) spectroscopy. Through a series of jar test experiments, the characterized alum samples were used to purify river water samples. Some of the parameters investigated include; pH, turbidity, total suspended solids (TSS), total dissolved solids (TDS), electrical conductivity (EC) and chemical oxygen demand (COD). The results show that the alum samples were able to reduce the turbidity by 100 % and substantially decrease the TSS, TDS and COD over the five-hour period of study. However, there were slight increases in acidity and EC which could be corrected by other methods [ABSTRACT FROM AUTHOR]

Published

2024

47. Integrating wastewater treatment to bio-stimulant & biochar generation for plant growth promotion using microalgae.

Author

Rawat, Jyoti, Nanda, Manisha, Kumar, Sanjay, Sharma, Nishesh, Sharma, Rohit, Joshi, Harish Chandra, Vlaskin, Mikhail S., Hussain, Afzal, and Kumar, Vinod

Subjects

*SUSTAINABILITY, *WASTEWATER treatment, *BIOCHEMICAL oxygen demand, *COMMON bean, *CHEMICAL oxygen demand

Abstract

The elevated level of pollutants in water highlights the urgency of effective wastewater treatment. Hence, the concern about the potential of microalgae as an economically and environmentally sustainable for wastewater treatment is addressed. Wastewater treatment using microalgae resulted in significant reductions in micropollutants by 82 % for chemical oxygen demand (COD) and biological oxygen demand (BOD). Iron (Fe) concentration was reduced by 99 %, while calcium (Ca) decreased by 25 %. Algal biomass obtained from wastewater is executed for biochar production and bio-stimulant preparation. Bio-stimulant treatment significantly enhanced seed germination and increased shoot and root lengths in maize (Zea mays) and beans (Phaseolus vulgaris) compared to the control. Conversely, seed germination was completely suppressed in both maize and beans in the presence of biochar of bio-stimulant treatment. The GC-MS and NMR analysis study revealed the presence of key compounds in the microalgal extract that have a great contribution to plant growth. Hence, the study concludes the multifaceted and potential application of microalgae as a remediation and bio-stimulant in a sustainable way. [Display omitted] • Integrated wastewater treatment, recycling and reuse technology (SDG 6a). • Utilization of wastewater treated C. sorokiniana for biochar & bio stimulant generation. • Bio-stimulant influenced germination and growth of Zea Maize and Phaseolus vulgaris. • GC-MS analysis identified key compounds in bio-stimulant for plant growth promotion. [ABSTRACT FROM AUTHOR]

Published

2024

48. 广西银滩南部海域海洋牧场鱼类群落结构特征及其与环境 因子的关系.

Author

于 杰, 邹建伟, and 陈国宝

Subjects

FISH communities, CHEMICAL oxygen demand, FISHERY resources, MARINE resources, FISH surveys

Abstract

Copyright of South China Fisheries Science is the property of South China Fisheries Science Editorial Department and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

49. Low Strength Wastewater Treatment Using a Combined Biological Aerated Filter/Anammox Process.

Author

Xie, Wanying, Li, Ji, Song, Tao, Li, Yong, Wang, Zhenlin, and Zhang, Xiaolei

Subjects

NITROGEN removal (Sewage purification), PROCESS capability, EFFLUENT quality, CHEMICAL oxygen demand, WASTEWATER treatment

Abstract

To achieve the in situ capacity expansion of the post-denitrification biological aerated filter (BAF-DN), the integration of BAF with the anammox process (BAF/AX) was proposed. With the objective of maximizing retaining ammonia nitrogen, the operational optimization of BAF was achieved by two distinct strategies. The treatment performance of BAF demonstrated that the removal efficiencies of chemical oxygen demand (COD) and ammonia nitrogen ( NH 4 + - N ) was 66.3~67.3% and 4~12%, respectively, under conditions of low aeration intensity (0.4 m3·m−2·h−1) or a shortened empty bed residence time (EBRT) of 30 min. Residual NH 4 + - N in the BAF effluent served as the ammonia substrate for the subsequent anammox process, which was successfully launched by using ceramic particles and sponges as carriers. Notably, the sponge carrier facilitated a shorter start-up period of 41 to 44 days. Furthermore, the sponge-based anammox reactor exhibited a superior NH 4 + - N removal capacity (≥85.7%), under operations of a shorter EBRT of 40 min, low influent NH 4 + - N concentrations (≤30 mg/L), and COD levels of ≤67 mg/L. In addition, a comprehensive evaluation of the BAF/AX process was conducted, which considered performance, cost-effectiveness, and engineering feasibility. The performance results illustrated that the effluent quality met the standard well (with a COD level of ≤ 50 mg/L, and a TN of ≤3.1~10.5 mg/L). Following a comparison against the low aeration intensity operation, it was recommended to operate BAF at a low EBRT within the BAF/AX process. Consequently, the treated volume was double the volume of the standalone BAF-DN, synchronously achieving low costs (0.413 yuan/m3). [ABSTRACT FROM AUTHOR]

Published

2024

50. A Novel Algal–Algal Microbial Fuel Cell for Enhanced Chemical Oxygen Demand Removal.

Author

Zhang, Yuting, Cheng, Kai, Mei, Hong, and Qin, Wensheng

Subjects

SYNTHETIC fuels, CHEMICAL oxygen demand, WASTEWATER treatment, FUEL systems, MICROALGAE, MICROBIAL fuel cells

Abstract

To enhance the removal of COD (Chemical Oxygen Demand) by microalgae, this study constructed a novel microalgae–microalgae microbial fuel cell system (AA-MFC). It investigated the coupling relationship between the COD treatment efficiency at the anode and the production of high-value microalgal products at the cathode, as well as explored the effects of different initial inoculum densities and light–dark cycles. The experiment first measured the operational performance of the newly constructed AA-MFC in open-circuit and closed-circuit modes, demonstrating that this novel AA-MFC could start up rapidly within 32 h and operate stably. The results showed that the AA-MFC enhanced the removal of COD and the growth of microalgae biomass at the anode while maintaining stable power generation. When the initial inoculation density of the anode was 1.2 × 108 cell/cm2 and the light–dark cycle time was 18:6 h, the AA-MFC had the most obvious promoting effect on the COD removal of the anode. Compared with normal culture conditions, the COD removal rate increased by 26.0% to 96.1%. These results indicate that the AA-MFC can not only effectively remove pollutants, but also promote the accumulation of high-value microalgae biomass. [ABSTRACT FROM AUTHOR]

Published

2024