Your search keyword '"Biofiltration"' showing total 3,285 results

1. Exploring naphthalene vapor biofiltration: performance and microbial community dynamics with diverse inoculums.

Author

San Martín‐Davison, Jessica, Lebrero, Raquel, Vergara‐Ojeda, Christian, Scott, Felipe, Huiliñir, Cesar, and Vergara‐Fernández, Alberto

Subjects

POLYCYCLIC aromatic hydrocarbons, RHODOCOCCUS erythropolis, BIOFILTRATION, BIOFILTERS, FUSARIUM solani

Abstract

Background: Naphthalene is a polycyclic aromatic hydrocarbon, highly dangerous for human health. It is produced as a byproduct of incomplete combustion of organic material and is frequently present in the air. Biofilters offer an effective alternative for its treatment. The aim of this work was to study the treatment of naphthalene vapors through biofiltration using two biofilters: one inoculated with a consortium composed of Fusarium solani and Rhodococcus erythropolis (BF1), and the other inoculated with a consortium of microbial isolates obtained from a previous biofilter eliminating naphthalene vapors. Results: The results demonstrate that inoculating a biofilter with a reconstructed consortium of microbial isolates from a naphthalene vapor‐eliminating biofilter allowed a reduction of the startup time from 35 to 5 days, while maintaining a consistent removal capacity (6 g m−3 h−1, equivalent to 80% removal efficiency). It was also observed that the biofilter inoculated with the reconstructed consortium exhibited comparable robustness to a biofilter previously operated for 4 months with naphthalene, with a maximum removal capacity of 14 g m−3 h−1 for a naphthalene inlet load of 17 g m−3 h−1. The study of microbial communities indicates an increase in the bacterial variability, while fungal variability remains low, with Fusarium solani being predominant at 97%. Conclusions: Results obtained during the startup of both biofilters and by challenging biofilters to increasing naphthalene concentrations or decreasing empty bed residence time showed that startup time can be reduced sevenfold by selecting the microbial consortium. An equivalent performance, in the long run, was achieved for both biofilters. © 2024 Society of Chemical Industry (SCI). [ABSTRACT FROM AUTHOR]

Published

2024

2. Metataxonomic Analysis of Microbial Communities in Aquaponic Systems at Two Facilities in the Midwest United States.

Author

Rogge, Matthew L., Impullitti, Ann E., Phelps, Nicholas B. D., and Bailey, Christyn

Subjects

*MICROBIAL communities, *FISH waste, *PLANT nutrients, *BIOFILTRATION, *PLANT species

Abstract

Aquaponic production relies on microbial activity to convert fish wastes into nutrients for plants. An aquaponic system contains multiple compartments that each have varying environmental pressures that can impact the types of microbes living in the compartment. Furthermore, differences in fish and plant species, system startup and management, and water source can impact microbial communities that colonize an aquaponic system. In this study, we sampled two aquaponic facilities that each operated six replicate aquaponic systems. Metataxonomic analyses were performed on the samples to compare the microbial communities of aquaponic facilities in Minnesota (MN) and Wisconsin (WI), assess the consistency of the microbial communities across multiple systems within a single facility, and evaluate the abundance and types of microbes present within each compartment of a system. Proteobacteria, Bacteroidetes, and Actinobacteria were common in both facilities, but nitrifying organisms were in greater abundance at the WI facility. Microbial communities were largely consistent among systems within a facility, but microbial communities among different compartments of the systems varied. Nitrifying organisms were primarily associated with the biofilter compartment of the MN systems but were found throughout the WI systems, which do not have a dedicated biofiltration compartment. While nitrifying organisms have an important role in an aquaponic system, they comprise less than 10% of the total microbial community of the aquaponic systems we sampled. Other taxa are likely to have equally important roles in the productivity of an aquaponic system, but those taxa and their functions have not been well characterized, and it is unclear how system startup, management, and other factors impact colonization and maintenance of these taxa. [ABSTRACT FROM AUTHOR]

Published

2024

3. Recent developments in Artificial Neural Network (ANN), steady-state and transient modeling of gas-phase biofiltration process

Author

Basil Mustafa and Zarook Shareefdeen

Subjects

VOCs, Biofiltration, Biofilter, Models, Artificial Neural Network (ANN), Steady-state, Chemical engineering, TP155-156

Abstract

Biofilter technology has played a significant role over several decades in providing clean air through removal of Volatile Organic Compounds (VOCs) and odor causing chemicals such as hydrogen sulfide from industrial polluted airstreams. Biofilters where biological oxidation process takes place are designed and installed in numerous industrial facilities including chemical manufacturing, food processing, solid waste recycling and wastewater treatment plants to control emissions of VOCs, and odors in order to comply with the air emission regulations and to provide clean breathable air. Biofilter mathematical models under steady-state and transient conditions are essential in order to design, scale-up and predict biofilter performance under different operating conditions. Similarly, Artificial Intelligence (AI) through the use of Artificial Neural Network (ANN) modeling of biofiltration process is also becoming important. This research provides a detailed discussion and review of the recent (i.e., the last two decades) and important studies related to ANN, steady-state and transient biofilter models.

Published

2024

4. Research and Trends of Filtration for Removing Microplastics in Freshwater Environments.

Author

Garfansa, Marchel Putra, Zalizar, Lili, Husen, Syarif, Triwanto, Joko, Ramadani, Shefa Dwijayanti, Iswahyudi, Iswahyudi, and Ekalaturrahmah, Yenni Arista Cipta

Subjects

WATER pollution, BIBLIOMETRICS, BIOFILTRATION, MICROPLASTICS, FRESH water

Abstract

Microplastics (MPs) are a pollutant that increasingly threatens freshwater ecosystems and requires effective solutions for their removal. The aim of this study is to review current filtration methods used to remove MPs from freshwater environments. This study uses a systematic review method of existing literature regarding filtration techniques for removing MPs. Data were collected from various scientific sources published between 2015 and 2023. The filtration techniques analyzed include traditional filtration and advanced filtration technology. The study results show that advanced filtration technologies such as nanofiltration and biofiltration have a high potential in removing MPs from freshwater. However, each technique has its own challenges, including removal efficiency and implementation cost. The conclusion is that filtration is an effective method for dealing with MP pollution in freshwater ecosystems; however, further study is needed to address the existing challenges. This study provides in‐depth insights that can help develop more efficient policies and technologies for managing MP pollution in the future. [ABSTRACT FROM AUTHOR]

Published

2024

5. Exploring the potential of biofiltration for mitigating harmful gaseous emissions from small or old landfills: a review.

Author

Merouani, El Farouk Omar, Ferdowsi, Milad, Buelna, Gerardo, Jones, J. Peter, Benyoussef, El-Hadi, Malhautier, Luc, and Heitz, Michèle

Subjects

LANDFILL gases, LANDFILLS, BIOFILTRATION, WASTE management, GREENHOUSE gas mitigation, VOLATILE organic compounds, GREENHOUSE gas analysis

Abstract

Landfills are widely employed as the primary means of solid waste disposal. However, this practice generates landfill gas (LFG) which contains methane (CH4), a potent greenhouse gas, as well as various volatile organic compounds and volatile inorganic compounds. These emissions from landfills contribute to approximately 25% of the total atmospheric CH4, indicating the imperative need to valorize or treat LFG prior to its release into the atmosphere. This review first aims to outline landfills, waste disposal and valorization, conventional gas treatment techniques commonly employed for LFG treatment, such as flares and thermal oxidation. Furthermore, it explores biotechnological approaches as more technically and economically feasible alternatives for mitigating LFG emissions, especially in the case of small and aged landfills where CH4 concentrations are often below 3% v/v. Finally, this review highlights biofilters as the most suitable biotechnological solution for LFG treatment and discusses several advantages and challenges associated with their implementation in the landfill environment. [ABSTRACT FROM AUTHOR]

Published

2024

6. Mathematical modeling and machine learning-based optimization for enhancing biofiltration efficiency of volatile organic compounds.

Author

Sulaiman, Muhammad, Khalaf, Osamah Ibrahim, Khan, Naveed Ahmad, Alshammari, Fahad Sameer, and Hamam, Habib

Subjects

*BIOFILTRATION, *SUPERVISED learning, *MACHINE learning, *BURGERS' equation, *MATHEMATICAL models, *VOLATILE organic compounds

Abstract

Biofiltration is a method of pollution management that utilizes a bioreactor containing live material to absorb and destroy pollutants biologically. In this paper, we investigate mathematical models of biofiltration for mixing volatile organic compounds (VOCs) for instance hydrophilic (methanol) and hydrophobic (α -pinene). The system of nonlinear diffusion equations describes the Michaelis-Menten kinetics of the enzymic chemical reaction. These models represent the chemical oxidation in the gas phase and mass transmission within the air-biofilm junction. Furthermore, for the numerical study of the saturation of α -pinene and methanol in the biofilm and gas state, we have developed an efficient supervised machine learning algorithm based on the architecture of Elman neural networks (ENN). Moreover, the Levenberg-Marquardt (LM) optimization paradigm is used to find the parameters/ neurons involved in the ENN architecture. The approximation to a solutions found by the ENN-LM technique for methanol saturation and α -pinene under variations in different physical parameters are allegorized with the numerical results computed by state-of-the-art techniques. The graphical and statistical illustration of indications of performance relative to the terms of absolute errors, mean absolute deviations, computational complexity, and mean square error validates that our results perfectly describe the real-life situation and can further be used for problems arising in chemical engineering. [ABSTRACT FROM AUTHOR]

Published

2024

7. Removal Characteristics of Gas-Phase D-Limonene in Biotrickling Filter and Stoichiometric Analysis of Biological Reaction Using Carbon Mass Balance.

Author

Choi, Youngyu and Kim, Daekeun

Subjects

*ENVIRONMENTAL quality, *BIOFILTRATION, *VOLATILE organic compounds, *MANUFACTURING processes, *CARBON

Abstract

Volatile organic compounds (VOCs) pose significant risks to human health and environmental quality, prompting stringent regulations on their emissions from various industrial processes. Among VOCs, d-limonene stands out due to its low threshold and contribution to malodorous emissions. While biofiltration presents a promising approach for VOC removal, including d-limonene, a comprehensive understanding of its performance and kinetics is lacking. This study aims to comprehensively assess the performance of a lab-scale biotrickling filter in treating gas-phase d-limonene. The experimental results indicate that the biotrickling filter efficiently removed d-limonene, achieving a critical loading rate of 19.4 g m−3 h−1 and a maximum elimination capacity of 31.8 g m−3 h−1 (correspondingly, up to 85% removal) at the condition of 94.2 s of EBRT. Microbial activity played a significant role in biotrickling filter performance, with a strong linear correlation being observed between CO2 production and substrate consumption. The Michaelis–Menten model was employed to represent enzyme-catalyzed reactions, suggesting no inhibition during biotrickling filter operation. [ABSTRACT FROM AUTHOR]

Published

2024

8. Fixed bed mycofilter column optimization and performance evaluation through the removal of a food coloring agent from an aqueous solution.

Author

Mnkandla, Sanele M. and Voua Otomo, Patricks

Subjects

*FOOD color, *PLEUROTUS ostreatus, *FUNGAL remediation, *ADSORPTION capacity, *AQUEOUS solutions

Abstract

Mycofiltration via continuous fixed bed adsorption, helped to assess the effect of flow rate, pH, column bed height and myceliation on the sorption capacity of a mycofilter. The mycofilter (thatching straw and Pleurotus ostreatus) was cultured and loaded into polypropylene columns (2.5 × 12 cm) to bed heights of 2 and 4 cm. A food color solution was passed through at different pH (2 and 7.5) and flow rates (0.25 ml/min and 2 ml/min). The filtrate was collected and measured at time intervals. Under constant flow rate and solution pH, the 4 cm bed adsorbed 8 times the inlet amount of food color compared to 1.6 times only for the 2 cm bed. More food color was adsorbed with the higher flow rate (10 times the inlet concentration). Adsorption was only observed in the solution with pH = 2. The control filter (without mycelia) adsorbed 3-fold less than the mycofilter. The experimental data best fitted into the Thomas model (compared to the Yoon-Nelson model) which showed that an increase in bed height caused an increase in adsorption capacity (qTH), and that an increase in flow rate resulted in an increase in Thomas rate constant (KTH). FTIR analyses of the mycofilter revealed amide, hydroxyl, and chitin groups possibly involved in adsorption processes. Our fixed bed mycofilter optimally removed food color from aqueous solutions, in high bed height and flow rate, and low pH conditions. [ABSTRACT FROM AUTHOR]

Published

2024

9. Recent Advances in Biofiltration for PPCP Removal from Water.

Author

Lin, Pinyi, Liao, Zhuwei, Wu, Gequan, Yang, Liwei, Fu, Jie, and Luo, Yin

Subjects

BIOFILTRATION, EMERGING contaminants, AGRICULTURAL pollution, WATER purification, WATER filtration, HYGIENE products, FILTERS & filtration

Abstract

As emerging pollutants, pharmaceuticals and personal care products (PPCPs) in water have attracted more and more attention because of their harmfulness to the ecosystem and human health. Due to the perpetual input from sewage/wastewater effluents, landfill leachates, urban/agricultural runoff, etc., PPCPs in the aquatic environment are generally "pseudo-persistent". Conventional filtration in the water treatment process cannot effectively remove PPCPs, while biofiltration, a synergistic combination of adsorption and biodegradation, is an effective upgrade method that has received great attention and application in recent years. This paper systematically reviewed the principle of biofiltration and its efficiency in the removal of PPCPs. The important operational parameters influencing biofiltration performance such as filter media, temperature, backwash conditions, empty bed contact time, etc. were summarized. In addition, the limitations and prospects of the current research on biofiltration were also pointed out. [ABSTRACT FROM AUTHOR]

Published

2024

10. Experimental assessment and artificial neural network modeling of dynamic and steady-state methane biofiltration in the presence of volatile organic compounds.

Author

Merouani, El Farouk Omar, Ferdowsi, Milad, Buelna, Gerardo, Jones, J. Peter, Malhautier, Luc, Heitz, Michèle, and Benyoussef, El-Hadi

Subjects

ARTIFICIAL neural networks, VOLATILE organic compounds, BIOFILTRATION, DYNAMIC models, METHANE

Abstract

This study examined the artificial neural network (ANN) modeling of simultaneous biofiltration of methane (CH4) with two volatile organic compounds (VOCs): xylene and ethylbenzene, using an inorganic packed bed biofilter at an empty bed residence time (EBRT) of 4.5 min. Results showed that the removal efficiency (RE) of CH4 was in the range of 50 to 60% for concentrations of 1000 to 10,000 ppmv (0.6 to 6.5 g m−3), while the VOCs-REs were between 70 and 90% for X and EB concentrations in the range of 200 to 500 ppmv (0.9 to 2.2 g m−3). Artificial neural networks were used to predict and simulate the performances of the biofilter, based on a database containing previous biofiltration works. The ANN1 (architecture of 3 (input layer)-18 (hidden layer)-1 (output layer)) accurately predicted CH4 conversion at the pseudo-steadystate condition, while the ANN2 (4 (input layer)-18 (hidden layer)-2 (output layer)) predicted the simultaneous conversion of CH4 and VOCs with slightly lower accuracy than ANN1. The ANN3 (4 (input layer)-30 (hidden layer)-1 (output layer)) successfully predicted the acclimation period and final phase (CH4 concentration of 10,000 ppmv) of the biofilter but could not accurately predict the transient phases and showed differences (up to 20%) from experimental results once the CH4 concentration was changed. This study developed a decision support and prediction tool to anticipate the performance of biofilters in treating residual gases containing CH4 and VOCs, avoiding costs and delays associated with experimentation. [ABSTRACT FROM AUTHOR]

Published

2024

11. Operators Keep Pace With Industry Changes.

Author

Pizzi, Nick

Subjects

WATER purification, WATER quality

Abstract

Water treatment advances bring improved water quality but also difficult choices for water system operators. Over the past 50 years, plant operators have kept pace with these changes to ensure public health. [ABSTRACT FROM AUTHOR]

Published

2024

12. A comparison of the performance of bacterial biofilters and fungal–bacterial coupled biofilters in BTEp-X removal.

Author

Wang, Hai, Xue, Xiaojuan, Nan, Xujun, and Zhai, Jian

Subjects

SEWAGE disposal plants, BIOFILTERS, AROMATIC compounds, BIOFILTRATION, MICROBIAL communities

Abstract

Background: Conventional biofilters, which rely on bacterial activity, face challenges in eliminating hydrophobic compounds, such as aromatic compounds. This is due to the low solubility of these compounds in water, which makes them difficult to absorb by bacterial biofilms. Furthermore, biofilter operational stability is often hampered by acidification and drying out of the filter bed. Methods: Two bioreactors, a bacterial biofilter (B-BF) and a fungal–bacterial coupled biofilter (F&B-BF) were inoculated with activated sludge from the secondary sedimentation tank of the Sinopec Yangzi Petrochemical Company wastewater treatment plant located in Nanjing, China. For approximately 6 months of operation, a F&B-BF was more effective than a B-BF in eliminating a gas-phase mixture containing benzene, toluene, ethylbenzene, and para-xylene (BTEp-X). Results: After operating for four months, the F&B-BF showed higher removal efficiencies for toluene (T), ethylbenzene (E), benzene (B), and para-X (p-Xylene), at 96.9%, 92.6%, 83.9%, and 83.8%, respectively, compared to those of the B-BF (90.1%, 78.7%, 64.8%, and 59.3%). The degradation activity order for B-BF and F&B-BF was T > E > B > p-X. Similarly, the rates of mineralization for BTEp-X in the F&B-BF were 74.9%, 66.5%, 55.3%, and 45.1%, respectively, which were higher than those in the B-BF (56.5%, 50.8%, 43.8%, and 30.5%). Additionally, the F&B-BF (2 days) exhibited faster recovery rates than the B-BF (5 days). Conclusions: It was found that a starvation protocol was beneficial for the stable operation of both the B-BF and F&B-BF. Community structure analysis showed that the bacterial genus Pseudomonas and the fungal genus Phialophora were both important in the degradation of BTEp-X. The fungal-bacterial consortia can enhance the biofiltration removal of BTEp-X vapors. [ABSTRACT FROM AUTHOR]

Published

2024

13. Sustainable Livestock Production: Screening Analysis and Pilot Implementation of a Biofilm in Piggery Biofilters for Mitigation of Ammonia and Hydrogen Sulfide Emissions.

Author

Breza-Boruta, Barbara, Kanarek, Piotr, Paluszak, Zbigniew, Kaczorowska, Anna-Karina, and Gryń, Grzegorz

Subjects

SUSTAINABILITY, LIVESTOCK productivity, BIOFILTERS, SWINE housing, AMMONIA, HYDROGEN sulfide

Abstract

One of the most noticeable problems associated with the close location of piggeries is gaseous compounds emission. Ammonia and hydrogen sulfide emissions affect the quality of life of people living in the vicinity of such facilities. Among the diverse methods for managing and controlling malodorous substances, biological methods, which involve the utilization of microbiological agents, are widely employed. The use of bacterial strains is a relatively simple, low-cost, and ecological method. The study aimed to conduct a preliminary evaluation of the implementation of a novel consortium of deodorizing bacteria. The study involved the selection of bacteria, assessment of the antagonistic properties, implementation of the inoculum in a mesh-filled biofilter, and analysis of ammonia, hydrogen sulfide, and fine dust content in the air before and after passing through the mature biological bed. The results obtained demonstrate the effectiveness of the biofiltration bed in reducing ammonia levels, with a maximum decrease observed at 73.90%. For hydrogen sulfide, a removal efficiency of >72.08% was observed. Reduction in fine dust pollution also decreased from a level of 3.75 mg/m3 to 1.06 mg/m3. The study's findings demonstrate the promising potential of utilizing a consortium of deodorizing bacteria as an effective approach to mitigating emissions from piggeries. [ABSTRACT FROM AUTHOR]

Published

2024

14. Species-specific influence of powdery mildew mycelium on the efficiency of PM accumulation by urban greenery.

Author

Przybysz, Arkadiusz, Nawrocki, Adam, Mirzwa-Mróz, Ewa, Paduch-Cichal, Elżbieta, Kimic, Kinga, and Popek, Robert

Subjects

MYCELIUM, ENGLISH oak, AIR pollutants, PARTICULATE matter, URBAN plants, BIOFILTRATION, POWDERY mildew diseases, URBAN trees

Abstract

Particulate matter (PM) is one of the most important air pollutants, especially in urban areas. The efficiency of PM biofiltration by plants depends on the morphological features of the foliage. More PM is deposited on complex leaves, covered with thick wax layer, trichomes, epidermal glands, and convex venation. Very few literature reports suggest that also the presence of mycelium of nonparasitic and saprophytic fungi positively affects the accumulation of PM on the leaves. In this work, to our best knowledge, for the first time the effect of the mycelium of the parasitic powdery mildew on the efficiency of PM accumulation by urban greenery was studied. Uninfested and fungus-infested leaves of Acer negundo L., Malus domestica Borkh Quercus robur L., and Berberis vulgaris L. were harvested in July in the center of Warsaw city. The effect of powdery mildew infection on PM accumulation was species-specific. A higher amount of PM on leaves not infected with powdery mildew was found in M. domestica and Q. robur, while in A. negundo and B. vulgaris more PM was accumulated on leaves infected with fungus. All species (except A. negundo) accumulated more of the PM of 0.2–2.5-μm and 2.5–10-μm size fractions on leaves not infected with powdery mildew. One of the greatest consequences of the presence of powdery mildew mycelium on the foliage is most probably reduction of the direct involvement of waxes in PM accumulation and retention processes. [ABSTRACT FROM AUTHOR]

Published

2024

15. Prolonged operation of a methane biofilter from acclimation to the failure stage.

Author

Ferdowsi, Milad, Khabiri, Bahman, Buelna, Gerardo, Jones, J. Peter, and Heitz, Michèle

Subjects

GREENHOUSE gas mitigation, BIOFILTERS, METHANE, ACCLIMATIZATION

Abstract

Global warming needs immediate attention to reduce major greenhouse gas emissions such as methane (CH4). Bio-oxidation of dilute CH4 emissions in packed-bed bioreactors such as biofilters has been carried out over recent years at laboratory and large scales. However, a big challenge is to keep CH4 biofilters running for a long period. In this study, a packed-bed lab-scale bioreactor with a specialized inorganic-based filter bed was successfully operated over four years for CH4 elimination. The inoculation of the bioreactor was the active leachate of another CH4 biofilter which resulted in a fast acclimation and removal efficiency (RE) reached 80% after seven weeks of operation for CH4 inlet concentrations ranging from 700 to 800 ppmv and an empty bed residence time (EBRT) of 6 min. During four years of operation, the bioreactor often recorded REs higher than 65% for inlet concentrations in the range of 1900–2200 ppmv and an EBRT of 6 min. The rate and interval of the nutrient supply played an important role in maintaining the bioreactor's high performance over the long operation. Forced shutdowns were unavoidable during the 4-year operation and the bioreactor fully tolerated them with a partial recovery within one week and a progressive recovery over time. In the end, the bioreactor's filter bed started to deteriorate due to a long shutdown of twelve weeks and the extended operation of four years when the RE dropped to below 8% with no sign of returning to its earlier performance. [ABSTRACT FROM AUTHOR]

Published

2024

16. Biofiltration of toluene in the presence of ethyl acetate or n-hexane: Performance and microbial community.

Author

Xue, Xiaojuan, Wang, Hai, Zhai, Jian, and Nan, Xujun

Subjects

*BIOFILTRATION, *HEXANE, *TOLUENE, *MICROBIAL communities, *ETHYL acetate, *VOLATILE organic compounds, *NUCLEOTIDE sequencing, *BEDTIME

Abstract

This study describes the operation of two independent parallel laboratory-scale biotrickling filters (BTFs) to degrade different types of binary volatile organic compound (VOC) mixtures. Comparison experiments were conducted to evaluate the effects of two typical VOCs, i.e., ethyl acetate (a hydrophilic VOC) and n-hexane (a hydrophobic VOC) on the removal performance of toluene (a moderately hydrophobic VOC) in BTFs "A" and "B", respectively. Experiments were carried out by stabilizing the toluene concentration at 1.64 g m−3 and varying the concentrations of gas-phase ethyl acetate (0.85–2.8 g m−3) and n-hexane (0.85–2.8 g m−3) at an empty bed residence time (EBRT) of 30 s. In the presence of ethyl acetate (850 ± 55 mg m-3), toluene exhibited the highest removal efficiency (95.4 ± 2.2%) in BTF "A". However, the removal rate of toluene varied from 48.1 ± 6.9% to 70.1 ± 6.8% when 850 ± 123 mg m-3 to 2800 ± 136 mg m-3 of n-hexane was introduced into BTF "B". The high-throughput sequencing data revealed that the genera Pseudomonas and Comamonadaceae_unclassified are the core microorganisms responsible for the degradation of toluene. The intensity of the inhibitory or synergistic effects on toluene removal was influenced by the type and concentration of the introduced VOC, as well as the number and activity of the genera Pseudomonas and Comamonadaceae_unclassified. It provides insights into the interaction between binary VOCs during biofiltration from a microscopic perspective. [ABSTRACT FROM AUTHOR]

Published

2024

17. Monitoring natural organic matter in drinking water treatment with photoelectrochemical oxygen demand.

Author

DeMont, Isobel, Anderson, Lindsay E., Bennett, Jessica L., Sfynia, Chrissa, Bjorndahl, Paul, Jarvis, Peter, Stoddart, Amina K., and Gagnon, Graham A.

Subjects

*ORGANIC compounds, *DRINKING water, *SEWAGE purification, *BIOFILTRATION, *ENVIRONMENTAL engineering

Abstract

Conventional metrics such as total organic carbon (TOC) and ultraviolet absorbance at 254 nm (UV254) may oversee aspects of natural organic matter (NOM) reactivity in drinking water treatment. The novel photoelectrochemical oxygen demand (peCOD) analyzer indirectly measures the oxygen consumed during NOM oxidation with photo‐ and electrochemical methods, quantifying NOM reactivity. peCOD was valuable for tracking NOM degradation in nine drinking water treatment facilities, particularly in processes where conventional metrics failed to capture changes in NOM from partial oxidation (e.g., biofiltration and oxidation). However, peCOD exhibited moderate correlations with TOC (R2 = 0.67) and UV254 (R2 = 0.48), indicating the need for its concurrent use with conventional methods. While peCOD was not a significant predictor of disinfection by‐product formation potential (R2 < 0.20), its inclusion alongside standard NOM metrics improved the performance of multivariable regression models. Thus, peCOD provided a rapid, standardized, operator‐friendly, environmentally conscious, concentration‐based approach for evaluating NOM characteristics in drinking water samples. [ABSTRACT FROM AUTHOR]

Published

2024

18. Mathematical Modelling of the Biofiltration Treating Mixtures of Toluene and n-Propanol in the Biofilm and Gas Phase.

Author

Visuvasam, J., Meena, A., and Rajendran, L.

Subjects

*BIOFILTRATION, *MATHEMATICAL models, *TOLUENE, *NONLINEAR differential equations, *PROPANOLS, *BIOFILMS

Abstract

In this paper, the mathematical model of the biofiltration of a mixture of n-propanol and toluene is developed based on the gasbiofilm phases. The homotopy perturbation technique is applied to get the approximate analytical expression for the concentration of toluene and n-propanol in non-steady-state conditions for both gasbiofilm interfaces. Our analytical results were validated by direct comparison with numerical simulations generated using the "bvp4c" function in the MATLAB platform. For various parameter values, the comparison was found to be in good agreement. The saturated and unsaturated kinetics also have been investigated analytically. [ABSTRACT FROM AUTHOR]

Published

2024

19. Laboratory Wastewater Treatment Using a Combination of Anaerobic Bioaccumulation Systems and Plant Biofiltration.

Author

Suyasa, Wayan Budiarsa, Sukarta, I. Nyoman, and Diantariani, Ni Putu

Subjects

WASTEWATER treatment, ANAEROBIC bacteria, BIOFILTRATION, FERMENTATION, BIOACCUMULATION

Abstract

Laboratory waste that is disposed of into the environment will have an impact on environmental pollution and threaten human health. Efforts to treat laboratory wastewater must be carried out. This research aimed to analyze the effectiveness of Anaerobic Bioaccumulation Systems with sulfate-reducing bacteria (SRB) in reducing heavy metals and sulfate ions as well as the effectiveness of plant biofiltration (PB) in reducing biological oxygen demand (BOD), chemical oxygen demand (COD) and heavy metals in laboratory wastewater compared to quality standards. In this research, a plant biosystem which uses the principle of phytoremediation was used to reduce the heavy metal content in wastewater. This anaerobic reactor is cylindrical with r of 0.23 m and t of 0.93 m and has a volume of 1.5 m³. In this tank, there is an SRB initial growth column with a volume 6.7 L. SRB media in the form of 30% compost fermentation solution, Postgate B nutrients with 10% sulfate added to the column. It stimulated with SRB seeds that had been isolated previously, then laboratory waste is added until it fills the column. After being acclimatized for 15 days, the laboratory wastewater began to flow slowly into anaerobic bioaccumulation system. The next stage was a plant filtration system in a size of basin 3.0x1.0x1.0 m with of 4 vertical layers. The bottom layer consists of 20% limestone, 30% coral and 50% sand. The plant used was Sansevieria trifasciata. The research results showed that the SRB Anaerobic Bioaccumulation was effective in reducing heavy metals and sulfate ions by up to 80.6% with a residence time of 24 hours after growing SRB for 15 days PB is effective in reducing BOD, COD and heavy metal content to meet the specified quality standards with a residence time of 30 hours after plant acclimatization for 15 days. The combination of the SRB anaerobic accumulation and PB system worked effectively with a total residence time of 2.25 days, which was marked by a decrease in all test parameters to below the specified quality standards. [ABSTRACT FROM AUTHOR]

Published

2024

20. Impacts of aquaculture nutrient sources: ammonium uptake of commercially important eucheumatoids depends on phosphate levels.

Author

Narvarte, Bienson Ceasar V., Hinaloc, Lourie Ann R., Gonzaga, Shienna Mae C., and Roleda, Michael Y.

Abstract

In an integrated multitrophic aquaculture (IMTA) system, seaweeds serve as extractive species that utilize excess nutrients, thereby reducing the risk of eutrophication and promoting sustainable aquaculture. However, the use of excessive fish feeds and the resultant faecal waste as nutrient streams can contribute to variations in nitrogen and phosphorus levels (e.g., primarily NH4+ and PO4−3) in the surrounding area and this may impact the physiology of the integrated seaweeds, particularly on how these species take up inorganic nutrients. In this study, the effect of different PO4−3 levels on NH4+ uptake of the three commercially important eucheumatoids Kappaphycus alvarezii, Kappaphycus striatus and Eucheuma denticulatum was examined under laboratory conditions. Seaweed thalli (n = 4) were incubated in seawater media containing 30 µM NH4+, and 0, 0.5, 1.0, 1.5, 3.0 or 5.0 µM PO4−3 for 1 h under a saturating light level of 116 ± 7.13 µmol photons m−2 s−1 inside a temperature-controlled laboratory. Species-specific responses to PO4−3 levels were observed. For K. alvarezii, maximum NH4+ uptake (17.8 ± 1.6 µmol gDW−1 h−1) was observed at 0.5 µM PO4−3 and the uptake rate declined at higher PO4−3 levels. For K. striatus, NH4+ uptake increased with increasing PO4−3 levels, with maximum N uptake (6.35 ± 0.9 µmol gDW−1 h−1) observed at 5.0 µM PO4−3. For E. denticulatum, maximum NH4+ uptake (14.6 ± 1.4 µmol gDW−1 h−1) was observed at 1.0 µM PO4−3. Our results suggest that among the three eucheumatoid species, the NH4+ uptake of K. striatus persists even at high levels of PO4−3. However, our results also showed that K. striatus had the lowest range of NH4+ uptake rates. These results should be taken into consideration when incorporating eucheumatoids in the IMTA system, where PO4−3levels significantly vary in space and time. [ABSTRACT FROM AUTHOR]

Published

2024

21. Improved greywater quality after biofiltration with a fibre-biofilter derived from plantain pseudo stem

Author

Abdul Rahim Mohammed, Francis Attiogbe, and Ismaila Emahi

Subjects

Biofiltration, Sustainable solutions, Organic matter removal, Biochemical oxygen demand, Chemical oxygen demand, Science

Abstract

In this study, we addressed the prevalent issue of untreated greywater discharge into waterbodies in many developing countries, despite the associated public health risks. Our approach involved utilizing fibers extracted from plantain pseudo-stems to enhance the quality of greywater through simple biofiltration setups. Greywater sourced from the GETFund Hostel of the University of Energy and Natural Resources in Sunyani, Ghana, served as the focal point of our investigation. Through the application of this biofilter, we achieved notable reductions in two crucial parameters for assessing greywater quality: biochemical oxygen demand (BOD) and chemical oxygen demand (COD), averaging at 30.4 % and 28.67 %, respectively. Furthermore, we conducted comparative analyses between the efficacy of plantain pseudo-stem fibers and carbonized coconut shell adsorbent, both individually and in composite form as biosorbents. While certain combinations of biofilters led to slight increases in conductivity, pH, and total dissolved solids (TDS) in the treated greywater, these variations were anticipated and attributed to potential organic matter leaching during the biofiltration process. Employing Fourier-transform infrared (FT-IR) spectroscopy, we detected significant spectral changes indicative of successful organic matter removal from the greywater. Specifically, we observed an intensified phenolic hydroxyl (OH) peak at 3300 cm⁻¹, which shifted marginally to 3335 cm⁻¹ post-biofiltration. Additionally, the emergence of a carboxylic hydroxyl stretch at 2850 cm⁻¹ post-biofiltration provided strong evidence supporting the efficacy of our approach in mitigating organic contaminants in greywater.

Published

2024

22. Estrutura e predição funcional da comunidade microbiana presente em biofiltro de escala real para tratar o odor de águas residuais

Author

Maria Joana Allievi, Maurício Egídio Cantão, Tiago Palladino Delforno, Luana Mattos de Oliveira Cruz, Daniele Damasceno Silveira, and Paulo Belli Filho

Subjects

wastewater odor, biofiltration, hydrogen sulfide, 16s rrna metagenomic sequencing, microbial dynamics structure, microbial functional prediction, Environmental technology. Sanitary engineering, TD1-1066, Environmental engineering, TA170-171, Environmental sciences, GE1-350

Abstract

A eficiência dos biofiltros depende da comunidade microbiana, portanto é crucial conhecer a dinâmica estrutural/funcional e identificar os principais gêneros microbianos ligados ao tratamento de gases tóxicos, como o sulfeto de hidrogênio (H2S). Este trabalho investigou a dinâmica estrutural ligada à predição funcional das comunidades microbianas de um biofiltro em escala real instalado próximo a uma estação elevatória de esgoto. A amostragem e a análise foram conduzidas por 720 dias. O sequenciamento Illumina 16S rRNA foi usado para avaliar o perfil taxonômico, seguido pela avaliação putativa de genes funcionais. A eficiência de remoção de H2S atingiu 90% da concentração do composto na entrada já na metade da altura do leito filtrante. A variável espacial teve maior efeito sobre a comunidade microbiana. Estudos focados no comportamento e estrutura bacteriana em sistemas de biofiltração ainda são escassos, e somente com mais pesquisas poderemos entender a dinâmica comportamental.

Published

2024

23. Methane Biofiltration Processes: A Summary of Biotic and Abiotic Factors

Author

Fatemeh Ahmadi, Tatiana Bodraya, and Maximilian Lackner

Subjects

biofiltration, greenhouse gases, methane emission, salinity, temperature, Biochemistry, QD415-436, Geophysics. Cosmic physics, QC801-809

Abstract

The ongoing yearly rise in worldwide methane (CH4) emissions is mostly due to human activities. Nevertheless, since over half of these emissions are scattered and have a concentration of less than 3% (v/v), traditional physical–chemical methods are not very effective in reducing them. In this context, biotechnologies like biofiltration using methane-consuming bacteria, also known as methanotrophs, offer a cost-efficient and practical approach to addressing diffuse CH4 emissions. The present review describes recent findings in biofiltration processes as one of the earliest biotechnologies for treating polluted air. Specifically, impacts of biotic (such as cooperation between methanotrophs and non-methanotrophic bacteria and fungi) and abiotic factors (such as temperature, salinity, and moisture) that influence CH4 biofiltration were compiled. Understanding the processes of methanogenesis and methanotrophy holds significant importance in the development of innovative agricultural practices and industrial procedures that contribute to a more favourable equilibrium of greenhouse gases. The integration of advanced genetic analyses can enable holistic approaches for unravelling the potential of biological systems for methane mitigation. This study pioneers a holistic approach to unravelling the biopotential of methanotrophs, offering unprecedented avenues for biotechnological applications.

Published

2024

24. Effect of applying a magnetic field on the biofiltration of hexane over long-term operation period

Author

Cortés-Castillo, Mónica, Encinas, Armando, Aizpuru, Aitor, and Arriaga, Sonia

Published

2024

25. Application of different packing media for the biofiltration of gaseous effluents from waste composting.

Author

Re, Andrea, Schiavon, Marco, Torretta, Vincenzo, Polvara, Elisa, Invernizzi, Marzio, Sironi, Selena, and Caruson, Paolo

Subjects

WOOD chips, BIOFILTRATION, SLUDGE composting, COMPOSTING, AIR pollution control, HYDROGEN sulfide, AIR analysis

Abstract

A pilot-scale experiment was implemented in a waste bioreactor with an inner capacity of 1 m3 in order to simulate a real-scale composting process. The waste underwent composting conditions that are typical of the initial bio-oxidation phase, characterised by a high production of volatile organic compounds (VOCs), hydrogen sulphide (H2S) and odorants. The waste bioreactor was fed with an intermittent airflow rate of 6 Nm3/h. The target of this study was to investigate the air treatment performance of three biofilters with the same size, but filled with different filtering media: (1) wood chips, (2) a two-layer combination of lava rock (50%) and peat (50%), and (3) peat only. The analyses on air samples taken upstream and downstream of the biofilters showed that the combination of lava rock and peat presents the best performance in terms of mean removal efficiency of odour (96%), total VOCs (95%) and H2S (77%) concentrations. Wood chips showed the worst abatement performance, with respective mean removal efficiencies of 90%, 88% and 62%. From the results obtained, it is possible to conclude that the combination of lava rock and peat can be considered as a promising choice for air pollution control in waste composting facilities. [ABSTRACT FROM AUTHOR]

Published

2024

26. Deodorizing bacterial consortium: community analysis of biofilms and leachate water collected from an air biofiltration system in a piggery.

Author

Paluszak, Zbigniew, Kanarek, Piotr, Gryń, Grzegorz, and Breza-Boruta, Barbara

Subjects

BIOFILTRATION, BACTERIAL communities, LEACHATE, SWINE housing, BIOFILMS, MICROBIOLOGICAL aerosols, GENE amplification, MICROBIOLOGICAL synthesis

Abstract

Intensive livestock production is a source of water, soil, and air contamination. The first aspect that negatively affects the quality of life of residents in the vicinity of piggeries is malodorous aerosols, which are not only responsible for discomfort but can be an etiological factor in the development of various diseases during prolonged exposure. One of the proven and efficient ways to counteract odor emissions is the usage of air biofiltration. The purpose of this study was to qualitatively analyze the bacterial community colonizing the biofilm of a biofilter operating at an industrial piggery in Switzerland. The study material consisted of biofilm and leachate water samples. The microbiological analysis consisted of DNA isolation, amplification of the bacterial 16S rRNA gene fragment (V3-V4), preparation of a library for high-throughput sequencing, high-throughput NGS sequencing, filtering of the obtained sequencing reads, and evaluation of the species composition in the studied samples. The investigation revealed the presence of the following bacterial genera: Pseudochelatococcus, Methyloversatilis, Flexilinea, Deviosia, Chryseobacterium, Kribbia, Leadbetterella, Corynebacterium, Flavobacterium, Xantobacter, Tessaracoccus, Staphylococcus, Thiobacillus, Enhydrobacter, Proteiniclasticum, and Giesbergeria. Analysis of the microbial composition of biofilters provides the opportunity to improve the biofiltration process. [ABSTRACT FROM AUTHOR]

Published

2024

27. The Influence of the Biofiltration Method on the Efficiency of Ammonium Nitrogen Removal from Water in Combined Sorption and Nitrification Processes.

Author

Papciak, Dorota, Domoń, Andżelika, and Zdeb, Monika

Subjects

BIOFILTRATION, NITRIFICATION, DRINKING water purification, AMMONIUM, SORPTION, NITROGEN removal (Water purification)

Abstract

This study assessed the impact of the method of conducting the biofiltration process on the efficiency of ammonium nitrogen removal from water in combined sorption and nitrification processes. The research was carried out on diatomite deposits using biofiltration with gravity and counter-gravity flow. The following physicochemical water parameters were controlled during the research, including ammonium nitrogen, nitrite nitrogen, nitrate nitrogen, and dissolved oxygen. Unconventional flow turned out to be more beneficial because it allows for optimal use of the entire bed surface, natural regulation of the biofilm thickness, and maintaining constant microbiological activity of the biofilm. The automatic regulation of the biofilm thickness during water flow prevented excessive growth of dead organic matter and limited the development of heterotrophic bacteria. Biofiltration with counter-gravity flow also resulted in reduced oxygen consumption. Regardless of the flow direction used, water after the single-stage biofiltration process was characterized by an increased content of nitrite nitrogen. The introduction of the second stage of filtration made it possible to obtain water that meets the requirements for water intended for human consumption. [ABSTRACT FROM AUTHOR]

Published

2024

28. Methane Biofiltration Processes: A Summary of Biotic and Abiotic Factors.

Author

Ahmadi, Fatemeh, Bodraya, Tatiana, and Lackner, Maximilian

Subjects

BIOFILTRATION, METHANOTROPHS, GREENHOUSE gases, BIOLOGICAL systems, AIR pollution

Abstract

The ongoing yearly rise in worldwide methane (CH4) emissions is mostly due to human activities. Nevertheless, since over half of these emissions are scattered and have a concentration of less than 3% (v/v), traditional physical–chemical methods are not very effective in reducing them. In this context, biotechnologies like biofiltration using methane-consuming bacteria, also known as methanotrophs, offer a cost-efficient and practical approach to addressing diffuse CH4 emissions. The present review describes recent findings in biofiltration processes as one of the earliest biotechnologies for treating polluted air. Specifically, impacts of biotic (such as cooperation between methanotrophs and non-methanotrophic bacteria and fungi) and abiotic factors (such as temperature, salinity, and moisture) that influence CH4 biofiltration were compiled. Understanding the processes of methanogenesis and methanotrophy holds significant importance in the development of innovative agricultural practices and industrial procedures that contribute to a more favourable equilibrium of greenhouse gases. The integration of advanced genetic analyses can enable holistic approaches for unravelling the potential of biological systems for methane mitigation. This study pioneers a holistic approach to unravelling the biopotential of methanotrophs, offering unprecedented avenues for biotechnological applications. [ABSTRACT FROM AUTHOR]

Published

2024

29. Green-wall based treatment for reclamation of greywater: A new approach.

Author

Pophali, Girish R., Bagde, Minakshi, and Labhasetwar, Pawan

Subjects

GRAYWATER (Domestic wastewater), WASTEWATER treatment, BIOFILTRATION, POLLUTANTS, IRRIGATION

Abstract

This paper presents reclamation of greywater using "Green-wall treatment system". A Green-wall of capacity 100 L/d has been implemented with the aim of greywater reclamation from a bathing water facility. The treatment system comprised of a degreasing tank of size 0.9 m x 0.9 m x 0.3 m for oil & grease removal, followed by a Green-wall. Removal of oil & grease has been done along with commonly observed pollutants in greywater, to prevent clogging of filler material. In stage-I studies, Green-wall pots are filled with 4-10 mm Ø inert filler material LECA and in stage-II, LECA is mixed with locally available coconut peat in equal proportion. Stage-I studies using LECA indicated that maximum achievable HRT is 12 h and the treated greywater with respect to BOD does not comply with USEPA (2012) norms for landscape irrigation. In stage-II, the optimized performance is observed at 16 &18 h HRT at hydraulic loading rate 67-70 L/m²/d, when compared with 14 and 12 h HRT. Treated greywater quality met the prescribed permissible limits with respect to BOD, TSS and FC and is observed to be innocuous in terms of the reuse options for agriculture and landscape irrigation. In stage-II, the BOD, COD, TSS and FC reduce from 48 to 10 mg/L, 58 to 18 mg/L, 96 to 10 mg/L and 400 CFU/ 100 mL to below detectable limits, respectively, at 18 h HRT. [ABSTRACT FROM AUTHOR]

Published

2024

30. Biofiltration of n-butyl acetate with three packing material mixtures, with and without biochar.

Author

Halecký, Martin, Mach, Jiří, Zápotocký, Luboš, Pohořelý, Michael, Beňo, Zdeněk, Farták, Josef, and Kozliak, Evguenii

Subjects

*BUTYL acetate, *BIOCHAR, *BIOFILTRATION, *NITROGEN fertilizers, *WOOD chips

Abstract

Two cost-effective packing materials were used for n-butyl acetate removal in lab-scale biofilters, namely waste spruce root wood chips and biochar obtained as a byproduct from a wood gasifier. Three biofilters packed with spruce root wood chips: without biochar (SRWC), a similar one with 10% of biochar (SRWC-B) and that with 10% of biochar impregnated with a nitrogen fertilizer (SRWC-IB) showed similar yet differing maximum elimination capacities of 206 ± 27, 275 ± 21 and 294 ± 20 g m−3 h−1, respectively, enabling high pollutant removal efficiency (>95% at moderate loads) and stable performance. The original biochar adsorption capacity was high (208 ± 6 mgtoluene g−1), but near 70% of it was lost after a 300-day biofilter operation. By contrast, the exposed impregnated biochar drastically increased its adsorption capacity in 300 days (149 ± 7 vs. 17 ± 5 mgtoluene g−1). Colony forming unit (CFU) and microscopic analyses revealed significant packing material colonization by microorganisms and grazing fauna in all three biofilters with an acceptable pressure drop, up to 1020 Pa m−1, at the end of biofilter operation. Despite a higher price (14 vs. 123 €m−3), the application of the best performing SRWC-IB packing can reduce the total investment costs by 9% due to biofilter volume reduction. [ABSTRACT FROM AUTHOR]

Published

2024

31. Toluene removal by pine cone/compost biofilter: determination of kinetic/operational parameters and substrate inhibitory effect.

Author

Kianpour, Sara, Hossaini, Hiwa, Pirsaheb, Meghdad, and Nourmoradi, Heshmatollah

Abstract

Toluene is one of 189 hazardous air pollutants proposed by the USEPA in the Clean Air Act Amendments of 1990. This aromatic hydrocarbon is capable to create many environmental and health effects, and is necessary to remove. In this study, biodegradation kinetic parameters and substrate inhibitory effect of toluene in pine cone/compost biofilter were investigated. The experiments were carried out at different flow rates (6.66, 9.6, and 12.5 L/min) and various concentrations of toluene (20, 70, 130, 180, 220, and 250 ppm). The removal efficiency in all phases reached 100% in the final port. As the concentration of toluene was increased to 250 ppm, the pressure drop was non-linearly increased. A maximum elimination capacity of 24.875 gm−3h−1 was achieved. The biofilm thickness was theoretically calculated to be 80 μm. The experimental results were compared with the value obtained from the Ottengraf–Vanden Oever model. The model demonstrated a good agreement between the calculated data and the physics of the process. [ABSTRACT FROM AUTHOR]

Published

2024

32. Lotus (Nelumbo nucifera): a multidisciplinary review of its cultural, ecological, and nutraceutical significance.

Author

Yang, Hang, He, Simai, Feng, Qi, Liu, Zisen, Xia, Shibin, Zhou, Qiaohong, Wu, Zhenbin, and Zhang, Yi

Subjects

EAST Indian lotus, SUSTAINABILITY, DIETARY fiber, BIOFILTRATION, CLIMATE change, GENITALIA

Abstract

This comprehensive review systematically examines the multifarious aspects of Nelumbo nucifera, elucidating its ecological, nutritional, medicinal, and biomimetic significance. Renowned both culturally and scientifically, Nelumbo nucifera manifests remarkable adaptability, characterized by its extensive distribution across varied climatic regions, underpinned by its robust rhizome system and prolific reproductive strategies. Ecologically, this species plays a crucial role in aquatic ecosystems, primarily through biofiltration, thereby enhancing habitat biodiversity. The rhizomes and seeds of Nelumbo nucifera are nutritionally significant, being rich sources of dietary fiber, essential vitamins, and minerals, and have found extensive culinary applications. From a medicinal perspective, diverse constituents of Nelumbo nucifera exhibit therapeutic potential, including anti-inflammatory, antioxidant, and anti-cancer properties. Recent advancements in preservation technology and culinary innovation have further underscored its role in the food industry, highlighting its nutritional versatility. In biomimetics, the unique "lotus effect" is leveraged for the development of self-cleaning materials. Additionally, the transformation of Nelumbo nucifera into biochar is being explored for its potential in sustainable environmental practices. This review emphasizes the critical need for targeted conservation strategies to protect Nelumbo nucifera against the threats posed by climate change and habitat loss, advocating for its sustainable utilization as a species of significant value. [ABSTRACT FROM AUTHOR]

Published

2024

33. Ozone: A Valuable Tool for Addressing Today's Environmental Issues. A Review of Forty-Five Years of Ozone: Science & Engineering.

Author

Loeb, Barry L.

Subjects

*OZONE, *RESEARCH personnel, *ENGINEERING, *WATER reuse, *EDITORIAL boards

Abstract

The first issue of Ozone: Science & Engineering (OS&E)was published in early 1979 with Dr L. J. Bollyky as theEditor-in-Chief. This was a milestone for the International Ozone Association, enabling professional recognition of the advances in ozone technology. Since this first issue, 45 volumes of Ozone: Science & Engineering have been published containing 238 individual issues, 1719 technical articles and nearly 22,000 pages. Dr Rip Rice became Editor-in-Chief in 1985 and continued this position until 1998. Barry Loeb was the editor until 2024. Under the leadership of these gentlemen, OS&E expanded from about 70 pages per issue four times per year to 100 pages, then to six issues per year, at about 100 pages. In 2001, the dimensions of the journal were increased to accommodate even more manuscripts. In 1989, the Harvey M. Rosen Memorial Award was established to recognize the "best paper" published in Ozone: Science & Engineering during the two-year period between World Congresses. The selection of this award is determined by the Editorial Board of Ozone: Science & Engineering. To date, 19 papers have received this prestigious award. OS&E has followed and reported the development of ozone technologies via peer reviewed articles from ozone researchers, manufacturers and consultants. This paper reviews the development of ozone technologies as reported by OS&E and summarizes how the technologies have evolved to meet environmental and other needs. [ABSTRACT FROM AUTHOR]

Published

2024

34. Experimental research on the selected biofiltration materials under dynamic conditions

Author

Kamyab Mohammadi and Rasa Vaiškūnaitė

Subjects

H2S removal, biofiltration, packing materials, physicochemical properties, Technology, Science

Abstract

Hydrogen sulfide (H2S) is a hazardous chemical compound present in raw biogas and requires removal. Biofiltration offers an eco-friendly solution by utilizing sulfur oxidizing bacteria (SOBs) within a biofilter. This biofilter typically comprises packing material to house SOBs and facilitate desulfurization. To optimize removal efficiency (RE), the physicochemical properties of packing materials (organic/inorganic/synthetic) need evaluation. This study focused on the characteristics of sewage sludge and biochar samples produced via pyrolysis at temperatures of 400 °C, 500 °C, and 600 °C, along with cellular concrete (CLC) waste and polyurethane foam (PUF). Measurements included bulk density, pH, and electrical conductivity, with discussion on their impact on H2S purification from biogas under dynamic conditions. Ultimately, PUF, CLC waste, biochar after 600 °C pyrolysis, and sewage sludge exhibited superior performance in terms of lowest bulk density, optimal pH, and highest electrical conductivity. Article in English. Eksperimentinis pasirinktos biofiltracijos medžiagos tyrimas dinaminėmis sąlygomis Santrauka Vandenilio sulfidas (H2S) yra vienas iš nepageidaujamų toksiškų cheminių junginių, esančių biodujose, todėl jį reikia pašalinti. Šių dujų biofiltravimas yra aplinkai nekenksmingas būdas. Įprastą biofiltrą sudaro filtravimo medžiaga kaip sieros oksiduojančių bakterijų gyvenamoji vieta. Siekiant optimizuoti H2S pašalinimo efektyvumą, eksperimentų metu turi būti įvertinta pasirinktų organinių filtravimo medžiagų fizikinių ir cheminių savybių įtaka biofiltravimo procesui. Tyrimo metu buvo nagrinėtos svarbiausios nuotekų dumblo mėginių charakteristikos ir bioanglis (po pirolizės: 400 °C, 500 °C ir 600 °C), taip pat akytojo betono atliekos ir poliuretano putos. Filtravimo medžiagų pasirinktos frakcijos buvo: mažesnės nei 0,6 mm ir nuo 0,6 mm iki 1 mm. Atlikti matavimai apėmė tūrinį tankį, pH ir elektrinį laidumą bei buvo aptartas šių savybių poveikis H2S valymui iš biodujų. Reikšminiai žodžiai: H2S šalinimas, biofiltravimas, pakavimo medžiagos, fizikinės ir cheminės savybės.

Published

2024

35. Prevention of water pollution through combined sewer overflow using high-speed biofiltration in urban watershed

Author

Ingyu Lee, Minsoo Kim, Antukh Tatsiana, Jung-joon Hwang, Yongjun Yoon, and Hyunook Kim

Subjects

Combined sewer overflow, Biofiltration, Biochemical Oxygen Demand (BOD), Environmental contamination, Removal efficiency, River, lake, and water-supply engineering (General), TC401-506, Water supply for domestic and industrial purposes, TD201-500, Energy industries. Energy policy. Fuel trade, HD9502-9502.5

Abstract

Over recent decades, the rural areas of Korea, including containing source waters, have become extensively developed. Combined sewer systems (CSSs) have been constructed to collect the sewage generated from these areas. Presently, it is common to experience localized heavy rain events, likely due to climate change, and sometimes, the volume of rainfall can become too high for a CSS to handle. In these cases, combined sewer overflow (CSOs) occurs, contaminating surface water, which may have been used as source water. Therefore, the Korean government will begin regulating the biochemical oxygen demand (BOD) of CSOs occurring during first flushes of less than 40 mg/L from 2024 onwards. In this study, a biofiltration-based technology was proposed to treat CSOs. Thus, this study aimed to remove BOD from CSO using this biofiltration system to contain cube-type media. For this, two different loading rates were tested on a pilot scale. Although the proposed system resulted in a footprint of only 10 % of that of a conventional activated sludge system, it was still capable of achieving efficient BOD removal. At a high loading rate, BOD removal efficiency was observed at approximately 53 %, and when this loading rate was reduced by 50 %, the removal efficiency was slightly improved to about 58 %. In both cases, the BODs of treated CSOs could be maintained below the proposed future standard: 31 mg/L and 28 mg/L for high and low loading rates, respectively. Therefore, the proposed system could potentially be preventing environmental contamination from COSs.

Published

2023

36. Differential utilisation of dissolved organic matter compound fractions by different biofilter microbial communities

Author

Marta Vignola, Jeanine Lenselink, Dominic Quinn, Umer Zeeshan Ijaz, Ryan Pereira, William T. Sloan, Stephanie Connelly, Graeme Moore, Caroline Gauchotte-Lindsay, and Cindy J. Smith

Subjects

biofiltration, community assembly, dissolved organic matter, lc-ocd, microbial degradation, Environmental technology. Sanitary engineering, TD1-1066, Environmental sciences, GE1-350

Abstract

Dissolved organic matter (DOM) is a complex mixture of carbon-based compounds present in natural aquatic systems, which significantly affects drinking water treatment processes. Biofiltration, utilising biologically active beds of porous medium, offers a low-energy and low-chemical solution for controlling bioavailable DOM. However, the impact of microbial community composition on DOM degradation in biofilters remains poorly understood. This study aimed to explore the abilities of microbial communities from the top, middle, and bottom (TOP, MID, and BOT) of a biofilter to process DOM. We showed varying growth rates on the DOM, with bottom community exhibiting the highest cell abundance at the end of the experiment (1.83 × 106 ± 9 × 103; 2.06 × 106 ± 1 × 104; 2.15 × 106 ± 7 × 103 cells/mL for the TOP, MID, and BOT, respectively). The three communities showed different preferences for utilising specific DOM fractions, with the bottom community targeting more complex ones. The microbial communities from the bottom of the biofilter had a higher relative abundance of the Curvibacter genus, suggesting it could play a crucial role in degrading complex DOM fractions. These findings highlight the influence of microbial community composition on DOM degradation in biofilters, providing valuable insights for optimising their performance. HIGHLIGHTS Communities were extracted from three different depths of a biofilter (TOP, MID, and BOT).; Communities differed in growth kinetics, with BOT showing the greatest growth.; The TOP and MID communities preferentially used the smaller fractions of DOM.; The BOT community used the more complex DOM fraction of humic substances.; Microbial communities from different depths of a biofilter exhibit distinct abilities to degrade DOM.;

Published

2023

37. Removal Characteristics of Gas-Phase D-Limonene in Biotrickling Filter and Stoichiometric Analysis of Biological Reaction Using Carbon Mass Balance

Author

Youngyu Choi and Daekeun Kim

Subjects

biofiltration, d-limonene, stoichiometric analysis, microbial kinetics, Meteorology. Climatology, QC851-999

Abstract

Volatile organic compounds (VOCs) pose significant risks to human health and environmental quality, prompting stringent regulations on their emissions from various industrial processes. Among VOCs, d-limonene stands out due to its low threshold and contribution to malodorous emissions. While biofiltration presents a promising approach for VOC removal, including d-limonene, a comprehensive understanding of its performance and kinetics is lacking. This study aims to comprehensively assess the performance of a lab-scale biotrickling filter in treating gas-phase d-limonene. The experimental results indicate that the biotrickling filter efficiently removed d-limonene, achieving a critical loading rate of 19.4 g m−3 h−1 and a maximum elimination capacity of 31.8 g m−3 h−1 (correspondingly, up to 85% removal) at the condition of 94.2 s of EBRT. Microbial activity played a significant role in biotrickling filter performance, with a strong linear correlation being observed between CO2 production and substrate consumption. The Michaelis–Menten model was employed to represent enzyme-catalyzed reactions, suggesting no inhibition during biotrickling filter operation.

Published

2024

38. Biodegradation Versus Composting

Author

Lee, Boon Hong, Khor, Sook Mei, Ali, Gomaa A. M., editor, and Makhlouf, Abdel Salam H., editor

Published

2023

39. Volatile Organic Compounds Impacts on Environment: Biofiltration as an Effective Control Method

Author

Rahul, Saxena, Reena, Kumar, Shravan, Pal, Dan Bahadur, Srivastava, Neha, Series Editor, Mishra, P. K., Series Editor, Pal, Dan Bahadur, editor, and Tiwari, Amit Kumar, editor

Published

2023

40. Greenhouse Gases Emissions Assessments and Mitigation Opportunities from Animal Manure Processing

Author

Ijaz, Muhammad Umar, Hayat, Muhammad Faisal, Safi, Sher Zaman, Hamza, Ali, Ashraf, Asma, Arshad, Muhammad, and Arshad, Muhammad, editor

Published

2023

41. Degradation of Selected Xenobiotics from Wastewater by Wood-Decay Fungi

Author

Žižlavská, Adéla, Hlavínek, Petr, Barceló, Damià, Series Editor, de Boer, Jacob, Editorial Board Member, Kostianoy, Andrey G., Series Editor, Garrigues, Philippe, Editorial Board Member, Hutzinger, Otto, Founding Editor, Gu, Ji-Dong, Editorial Board Member, Jones, Kevin C., Editorial Board Member, Knepper, Thomas P., Editorial Board Member, Negm, Abdelazim M., Editorial Board Member, Newton, Alice, Editorial Board Member, Nghiem, Duc Long, Editorial Board Member, Garcia-Segura, Sergi, Editorial Board Member, and Nasr, Mahmoud, editor

Published

2023

42. Air biofilters for a mixture of organic gaseous pollutants: an approach for industrial applications.

Author

Ferdowsi, Milad, Khabiri, Bahman, Buelna, Gerardo, Jones, J. Peter, and Heitz, Michèle

Subjects

*BIOFILTERS, *POLLUTANTS, *WASTE gases, *WASTE treatment, *AIR pollutants, *MICROBIAL diversity, *BIOSURFACTANTS

Abstract

Hazardous airborne pollutants are frequently emitted to the atmosphere in the form of a gaseous mixture. Air biofilters as the primary biotechnological choice for waste gas treatment (low inlet concentration and high gas flow rate) should run properly when the feed contains multiple pollutants. Simultaneous removal of pollutants in biofilters has been extensively studied over the last 10 years. In this review, the results and findings of the mentioned studies including different groups of pollutants, such as methane (CH4) and volatile organic compounds (VOCs) are discussed. As the number of pollutants in a mixture increases, their elimination might become more complicated due to interactions between the pollutants. Parallel batch studies might be helpful to better understand these interaction effects in the absence of mass transfer limitations. Setting optimum operating conditions for removal of mixtures in biofilters is challenging because of opposing properties of pollutants. In biofilters, concerns, such as inlet gas composition variation and stability while dealing with abrupt inlet load and concentration changes, must be managed especially at industrial scales. Biofilters designed with multi-layer beds, allow tracking the fate of each pollutant as well as analyzing the diversity of microbial culture across the filter bed. Certain strategies are recommended to improve the performance of biofilters treating mixtures. For example, addition of (bio)surfactants as well as a second liquid phase in biotrickling filters might be considered for the elimination of multiple pollutants especially when hydrophobic pollutants are involved. [ABSTRACT FROM AUTHOR]

Published

2023

43. Development of a CFD model indicating the quantitative relationship among reactor dimension, bed flow unevenness, and performance for VOCs biofilters.

Author

Liu, Ziyu, Dong, Dong, and Xi, Jinying

Subjects

*BIOFILTERS, *COMPUTATIONAL fluid dynamics, *BIOFILTRATION, *FLOW velocity, *CHEMICAL ionization mass spectrometry, *GAS flow

Abstract

This study presents a Computational Fluid Dynamics (CFD) based biofiltration model to investigate the airflow distribution and the impact of bed flow unevenness (BFU) on the removal of Volatile Organic Compounds (VOCs) in biofilters. The biofiltration model consists of a gas flow sub-model and a VOCs removal sub-model, which were validated by pilot-scale experiments. The model was used to examine the quantitative relationship among reactor dimensions, including the width to height ratio of the filter bed and empty bed residence time (EBRT), BFU, and performance for VOCs biofilters. Simulation results demonstrate that the flow unevenness index (FUI) of the packing layer changes from 0.06 to 0.48 m2‧s−1 with reactor dimension changes. With an increase in the width to height ratio at a constant EBRT, FUI increases, BFU changes, and flow velocity fluctuation on the cross-section becomes larger, leading to a reduction of about 10% in VOCs removal efficiency. Concentration distribution of VOCs becomes uneven in the horizontal direction. At a constant width to height ratio of the filter bed, an increase in EBRT causes an increase in FUI, leading to a decrease in VOCs removal efficiency. When the width to height ratio is 0.5, velocity fluctuation of filter bed cross-section is small, the concentration of VOCs decreases evenly across the filter bed layer, and FUI is at a low level (0.06–0.11 m2‧s−1). Implication: In this manuscript, a biofiltration model of VOCs biofilter based on CFD has constructed and validated. And the manuscript gave the quantitative relationship among reactor dimension, bed flow unevenness and performance for VOCs biofilters for the first time. This study can lead to enhanced VOCs removal efficiency and improved overall performance of biofilters in practical engineering applications. [ABSTRACT FROM AUTHOR]

Published

2023

44. Deodorisation of Industrial Gases Using a Biofiltration Plant.

Author

Wierzbińska, Monika

Subjects

INDUSTRIAL gases, NATURAL fibers, BIOFILTRATION, CARBON dioxide in water, WASTE gases, BIOMATERIALS

Abstract

This paper proposes the use of natural fibres: cotton, hemp and jute, as an additive to the fillings in peat-bark biofilters used to deodorise industrial gases in order to increase the sorption properties of the biomass used. The subject of the studies involved waste gases from a grease trap, which were passed through biofilters to remove volatile fatty acids (VFAs) from them that are responsible for the odour nuisance of these gases. It was assumed that a set of microorganisms would be established on the biological material through a process of natural selection to convert the readily decomposable fatty acids into carbon dioxide and water. Gases were sampled upstream and downstream of the beds as well as analysed qualitatively and quantitatively on a gas chromatograph. On the basis of the changes in volatile fatty acid concentrations, the efficiency of the deodorisation process was evaluated. The deodorisation results were compared between the individual beds at the unstable stage of those beds filtration, i.e. during the period of biofilters activation and during their stable filtration. For each bed, the efficiency during each week of filtration was calculated. The efficiencies of removal of individual fatty acids from the waste gases were also compared. The studies show that a 3-month filtration period of the biofilter is sufficient for the biological bed to begin to effectively perform its function as a deodoriser of waste gases under industrial conditions. This period was characterised by considerable turbulence and activation of both the filter material and the microorganisms in the bed. During the first weeks of activation, the beds described in this paper showed relatively low deodorisation efficiencies (33-58%). In the next phase, there was an increase in flow resistance and a partial decrease in treatment effects to 32-47%. After that, there were fluctuations in deodorisation efficiency for several weeks until the microflora was established and adapted. During this period, the peat-bark bed had the best efficiency amounting to 70-80%. After 9 weeks, the beds were already partially activated, the microorganisms were moving towards equilibrium and the deodorisation efficiency with fibre beds was above 80%. After 15 weeks of filtration, the already activated biofilters reached efficiencies of over 90% and even 95% in the case of cotton. [ABSTRACT FROM AUTHOR]

Published

2023

45. Simultaneous biofiltration of H2S, NH3, and toluene using compost made of chicken manure and sugarcane bagasse as packing material

Author

Guzmán-Beltrán, Ana María, Vela-Aparicio, Diana, Montero, Sergio, Cabeza, Iván O., and Brandão, Pedro F. B.

Published

2024

46. Process control of air stream deodorization from vapors of VOCs using a gas sensor matrix conducted in the biotrickling filter (BTF)

Author

Dominik Dobrzyniewski, Bartosz Szulczyński, Piotr Rybarczyk, and Jacek Gębicki

Subjects

biofiltration, electronic nose, biotrickling filter, chemical sensors, sensor matrix, odorous compounds, Environmental protection, TD169-171.8

Abstract

This article presents the validity, advisability and purposefulness of using a gas sensor matrix to monitor air deodorization processes carried out in a peat-perlite-polyurethane foam-packed biotrickling filter. The aim of the conducted research was to control the effectiveness of air stream purification from vapors of hydrophobic compounds, i.e., n-hexane and cyclohexane. The effectiveness of hydrophobic n-hexane and cyclohexane removal from air was evaluated using gas chromatography as the reference method and a custom-built gas sensor matrix consisting of seven commercially available sensors. The influence of inlet loading (IL) of n-hexane and cyclohexane on the biotrickling filtration performance was investigated. The prepared sensor matrix was calibrated with use of two statistical techniques: Multiple Linear Regression (MLR) and Principal Component Regression (PCR). The developed mathematical models allowed us to correlate the multidimensional signal from the sensor array with the concentration of the removed substances. The results based on gas chromatography analyses indicated that the elimination efficiencies of n-hexane and cyclohexane reached about 40 and 30 g m-3 h-1, respectively. The results obtained using a gas sensor matrix revealed that it was possible not only to determine concentration reliably of investigated hydrophobic volatile organic compounds in the gas samples, but also to obtain results of a similar high level of quality as the chromatographic ones. A gas-sensor matrix proposed in this work can be used for on-line real-time monitoring of biofiltration process performance of air polluted with n-hexane and cyclohexane.

Published

2023

47. The emergence and transfer of antibiotic-resistant bacteria and antibiotic resistance genes in aquatic environments : effects of plankton interactions

Author

Olanrewaju, Temilola, Arnscheidt, Joerg, and Dooley, James

Subjects

Horizontal gene transfer, Conjugation, Enterococcus faecalis, Biofiltration, Zooplankton, Daphnia, Tetrahymena, Microalgae

Abstract

The environmental dimensions of the global health problem of antibiotic resistance have remained largely uncharted, particularly in regard to biotic interactions of waterborne bacteria. This thesis studied the effect of phytoplankton and zooplankton on horizontal gene transfer (HGT) in Enterococcus faecalis strains in experimental microcosms. HGT was investigated between an E. faecalis donor strain with the plasmid borne vancomycin resistance gene vanA and rifampicin-resistant recipient strains. Gene transfer frequency (GTF) of vanA in centrifugation-induced liquid mating assays at 37 oC (10-7 ) significantly exceeded GTF at 20 oC or 30 oC (10-8). Enhanced nutrient availability increased GTF from 10-7 to 10-5 in liquid mating assays, thus documenting the importance of energy resources to conjugation in E. faecalis. Active filter feeding increased vanA GTF in Daphnia-bacteria microcosms to a range of 1.5 × 10-8 – 3.3 ×10-7, and ingested enterococci remained viable inside Daphnia for at least four days. Filter feeding zooplankton may thus facilitate the emergence of multi-resistance and disseminate transconjugants in aquatic environments. Microalgae zooplankton feeds on may further enhance HGT. Microcosm experiments documented that Palmellopsis sp. enhanced vanA GTF by an order of magnitude, indicating that the algal cell mucilage was a suitable attachment substrate and energy source for conjugation. The ciliate Tetrahymena pyriformis also facilitated HGT in E. faecalis. In the presence of live ciliates vanA GTF was 10-6 – 10-5 , an order of magnitude higher than in ciliate-free controls. GTF was higher within vesicles than in the ambient medium; it increased with time and peaked after 24 h. Overall, this thesis highlights the potential effects of interactions between eukaryotic freshwater organisms and Enterococcus faecalis as a representative of Gram positive bacteria on the emergence and spread of antibiotic resistance. It also offers a projection of gene transfer frequencies under environmentally relevant conditions in lakes and wastewater treatment plants.

Published

2020

48. Sustainable Livestock Production: Screening Analysis and Pilot Implementation of a Biofilm in Piggery Biofilters for Mitigation of Ammonia and Hydrogen Sulfide Emissions

Author

Barbara Breza-Boruta, Piotr Kanarek, Zbigniew Paluszak, Anna-Karina Kaczorowska, and Grzegorz Gryń

Subjects

biofilm, biofiltration, gaseous compounds control, deodorizing bacteria, pig farming, air pollution, Agriculture (General), S1-972

Abstract

One of the most noticeable problems associated with the close location of piggeries is gaseous compounds emission. Ammonia and hydrogen sulfide emissions affect the quality of life of people living in the vicinity of such facilities. Among the diverse methods for managing and controlling malodorous substances, biological methods, which involve the utilization of microbiological agents, are widely employed. The use of bacterial strains is a relatively simple, low-cost, and ecological method. The study aimed to conduct a preliminary evaluation of the implementation of a novel consortium of deodorizing bacteria. The study involved the selection of bacteria, assessment of the antagonistic properties, implementation of the inoculum in a mesh-filled biofilter, and analysis of ammonia, hydrogen sulfide, and fine dust content in the air before and after passing through the mature biological bed. The results obtained demonstrate the effectiveness of the biofiltration bed in reducing ammonia levels, with a maximum decrease observed at 73.90%. For hydrogen sulfide, a removal efficiency of >72.08% was observed. Reduction in fine dust pollution also decreased from a level of 3.75 mg/m3 to 1.06 mg/m3. The study’s findings demonstrate the promising potential of utilizing a consortium of deodorizing bacteria as an effective approach to mitigating emissions from piggeries.

Published

2024

49. The Role of Bacteria and Factors Affecting the Decomposition of Pollutants in the Biofilter Reactor: A Review

Author

Muliyadi Muliyadi, Purwanto Purwanto, Sri Sumiyati, Sudarno Sudarno, Budiyono Budiyono, Budi Warsito, and Hadiyanto Hadiyanto

Subjects

Biofiltration, Microorganisms, Decomposition of Pollutants, Wastewater, Environmental sciences, GE1-350, Environmental technology. Sanitary engineering, TD1-1066

Abstract

The findings showed that several types of bacteria can help biodegrade organic pollutants, such as Comamonadacea, which can biodegrade volatile fatty acids and aromatic compounds. Proteobacteria, Bacteroidetes, and Actinobacteria can biodegrade ammonium. Burkholderiales can biodegrade ferric ions and hydrogen. Comamonas testosteroni is able to biodegrade nitrates. Pseudomonas taiwanensis, Acinetobacter guillouiae, and Klebsiella pneumoniae can reduce copper, chromium and zinc levels. Azolla biomass reduces strontium. Rhodospirillum sp. can biodegrade cadmium, mercury, lead, and nickel. Gallionella ferruginea and Leptothrix sp. can biodegrade arsenic and manganese. Gracilaria sp. can biodegrade aluminum, chromium, and zinc. Desulfovibrio sp. can biodegrade copper, zinc, nickel, iron, and arsenic. Thiomonas sp. can biodegrade arsenic and iron. Thauera selenatis can biodegrade copper, zinc, cadmium, nickel, lead, cobalt, chromium, and mercury. Thiobacillus thiooxidans can degrade both zinc and copper. Sargassum filipendula biodegrades copper and nickel. Meanwhile, in the findings of the factors that affected biofiltration, it was identified that there were four that played a significant role such as temperature, dissolved oxygen, hydraulic retention time, organic loading rate, biological organisms, and supply nutrients. In conclusion, several types of bacteria grow and help biodegrade in biofilter reactors. This is inseparable from the supporting factors that increase the efficiency of pollutant reduction in biofilter reactors.

Published

2023

50. Mathematical modelling of the biofiltration treating mixtures of toluene and N-propanol in the biofilm and gas phase.

Author

Li, Shuguang, Chithra, S.M., Sudha, P.N., Sankeshwari, Sagar Ningonda, Vignesh, S., Vairavel, T. Muthukani, Govindan, Vediyappan, Abdalbagi, Mohamed, Fadhl, Bandar M., Makhdoum, Basim M., and Khan, M. Ijaz

Subjects

*BIOFILTRATION, *VOLATILE organic compounds, *TOLUENE, *NONLINEAR differential equations, *MATHEMATICAL models, *PARTIAL differential equations, *MICELLAR liquid chromatography, *FILTERS & filtration

Abstract

This paper presents a mathematical model in the biofilm phase and in the gas phase that has been successfully applied to investigate various aspects of the biofiltration process. The mixtures of volatile organic compounds (VOCs) are emitted from a wide range of industries, such as chemical, petrochemical, pharmaceutical, pulp paper mills, printing and paint workshops, etc. The objective of the present study is, presence of high n-propanol loading negatively affected the toluene removal; however, n-propanol removal was not affected by the presence of toluene and was effectively removed in the biofilter despite high toluene loadings. A model for toluene and n-propanol biofiltration could predict the cross-inhibition effect of n-propanol on toluene removal. Further, we studied the effects of many physical and biological parameters on model prediction. The mathematical equations (2.12)-(2.16) which are non-linear partial differential equations are solved by using the homotopy perturbation technique. Also, we derived the semi-analytical results for toluene and n -propanol concentrations for saturated and unsaturated kinetics. It is verified that the proposed solution is validated by comparing it with numerical solutions. • Here mathematical modelling is developed for bio-filtration in the biofilm phase. • The adopted model investigate various aspects of the bio-filtration process. • Analytical results is obtained via Homotopy Perturbation Technique. • The obtained solutions is verified for accuracy with existing literature. [ABSTRACT FROM AUTHOR]

Published

2023