Your search keyword '"Cost effective technology"' showing total 12 results

1. Mechanistic insight into cost-effective dedicated oxidation of alkanes by inactivating soil organic matter with FeOOH formed in situ.

Author

Li, Xiumin, Xu, Jinlan, Tian, Guiyong, Sun, Yanjie, Yang, Zhengli, and Yang, Zhilin

Subjects

*ORGANIC compounds, *SOIL remediation, *PETROLEUM, *HYDROXYL group, *ALKANES, *FENTON'S reagent

Abstract

Modified Fenton technique has been widely used to remediate soils contaminated with crude oil but significantly limited to soil organic matter (SOM) consuming oxidants. In this study, soils with developed SOM inactivation by FeOOH formed in situ were created and spiked with crude oil (total petroleum hydrocarbons (TPH): 19453 mg/kg), then treated by modified Fenton reagents. The reaction activity of hydroxyl radicals (•OH) relative to TPH (K) notably increased to 0.65 when the degree of developed inactivation of the SOM (β) was 100% (DIS-100), which was 1.45, 2.03 and 2.83-fold than that of DIS-50, DIS-15 and control (CK), respectively. Meanwhile, the higher the K, the more •OH transferred, which realized the efficient oriented oxidation of TPH. Moreover, improving the transfer of •OH from SOM to TPH was more important than increasing •OH production in soil remediation. With the β increasing to 100%, the ratio of invalid H 2 O 2 decomposition to produce O 2 decreased to 22%, equal to 25% reduction compared to CK. Therefore, when β was 100%, the utilization efficiency of H 2 O 2 was improved to 1.48 mg/mmol, which was approximately 1.39, 3.35 and 5.43-fold higher than the efficiency got by DIS-50, DIS-15 and CK, respectively, achieving the cost-effective dedicated oxidation of TPH. In addition, the FeOOH cross-linked with SOM via Fe–O–C and Fe–N bonds to develop inactivation of SOM. In general, this study highlighted a new insight into the effect of developed inactivation of SOM on soil remediation. [Display omitted] • Soil organic matter can be inactivated by cross-linking with FeOOH formed in situ. • FeOOH can cross-link with soil organic matter though Fe–O–C and Fe–N bonds. • The higher degree of developed inactivation SOM, the more.•OH was transferred. • Promoting.•OH transfer to TPH was more important than increasing •OH production. [ABSTRACT FROM AUTHOR]

Published

2022

2. Simultaneous nitrification and denitrification in a hybrid activated sludge-membrane aerated biofilm reactor (H-MABR) for nitrogen removal from low COD/N interflow: A pilot-scale study.

Author

Liu, Hengyi, Li, Lei, Ye, Wenjie, Zhao, Boxuan, Peng, Yun, Liu, Guotao, Gao, Xiaofeng, and Peng, Xuya

Subjects

*CHEMICAL oxygen demand, *SOLID waste, *LANDFILLS, *NITRIFICATION, *POLLUTANTS, *DENITRIFICATION

Abstract

There are a large number of simple landfills in hilly areas, and the results of previous studies have shown that pollutants in landfills can spread via interflow and cause surface source pollution. The hybrid activated sludge-membrane aerated bioreactor (H-MABR) developed in a previous study can be used for the treatment of interflow with a low chemical oxygen demand (COD)/total nitrogen (TN) ratio, and it has been shown to be effective in laboratory simulations. To investigate the effectiveness of the H-MABR in treating interflow around landfills in real-world applications, an in-situ pilot-scale evaluation of the effectiveness of H-MABR operation was conducted at a landfill. The results indicated that the removal efficiencies of COD, TN, and ammonia nitrogen in interflow by H-MABR were 87.1 ± 6.0%, 80.9 ± 7.9%, and 97.9 ± 1.4%, respectively. The removal rate of TN reached 148.6–205.6 g-N/m3·d. The concentration of each pollutant in the effluent was in accordance with China's "Standard for pollution control on the landfill site of municipal solid waste (GB16889-2008)," wherein the COD, TN, and ammonia nitrogen of effluent should be less than 100 mg/L, 40 mg/L, and 25 mg/L, respectively. The results of community composition analysis and PICRUSt analysis based on 16S rRNA gene sequencing showed that there were different dominant functional bacteria between the inner and outer rings, but functional genes involved in the nitrification-denitrification, assimilated nitrate reduction, and dissimilated nitrate reduction pathway were all detected. Furthermore, except for the nitrite oxidation gene narG , the abundance of which did not significantly differ between the inner and outer rings, the abundance of the other functional genes was higher in the outer ring than in the inner ring. An economic evaluation revealed that the operation cost of interflow treatment by the H-MABR was as low as ¥2.78/m3; thus, the H-MABR is a shock-load-resistant and cost-effective technology for interflow treatment. [Display omitted] • The performance of a H-MABR was studied under pilot-scale conditions. • The removal efficiencies of COD and TN reached 87.06 ± 6.04% and 80.86 ± 7.90%, respectively. • The TN removal rate of H-MABR reached 148.6–205.6 g-N/m3·d. • The operation costs of H-MABR were low (¥2.78/m3). [ABSTRACT FROM AUTHOR]

Published

2024

3. Unravelling the impact of light, temperature and nutrient dynamics on duckweed growth: A meta-analysis study.

Author

Pasos-Panqueva, Johan, Baker, Alison, and Camargo-Valero, Miller Alonso

Subjects

*NUTRIENT pollution of water, *TEMPERATURE control, *WASTEWATER treatment, *FLOWERING of plants, *PORTULACA oleracea

Abstract

Nature-based solutions have been proven in recent decades as a reliable and cost-effective technology for the treatment of wastewaters. Different plant species have been studied for this purpose, but particular attention has been given to duckweeds, the smallest flowering plant in the world. Duckweed-based systems for simultaneous wastewater treatment and nutrient recovery have the potential to provide sustainable and cost-effective solutions to reduce water pollution and increase nutrient efficiency at catchment level. However, despite being considered a seemingly simple technology, the performance of wastewater treatment systems using duckweed depends on environmental and operational conditions not very well understood. For that reason, careful consideration must be given to such environmental factors controlling duckweed biomass growth but the evidence in published literature is scare and dispersed. This study employs a systematic review approach to conduct a meta-analysis of the effect of environmental conditions on duckweed growth by means of standardised IQ-scores. The results suggest that duckweed biomass growth rates reach a maximum within specific ranges for temperature (11.4–32.3 °C), daily light integral (DLI) (5–20 mol m−2), and nitrogen (>5 mg N L−1) and phosphorus (>1 mg P L−1) concentrations; DLI was found to be a better parameter to assess the overall effect of light (photoperiod and intensity) on duckweed growth and that the effect of nitrogen and phosphorus supply should consider the nitrogen species available for plant growth and its ratio to phosphorus concentrations (recommended N:P ratio = 15:1). By establishing the optimal range of culture conditions for duckweed, this study provides important insights for optimizing engineered wastewater treatment systems that rely on duckweed for nutrient control and recovery, which is primarily mediated by duckweed growth. [Display omitted] • A meta-analysis with standardised scores can help to compare duckweed growth studies. • Different duckweed genera have different temperature optima. • The daily light integral is a useful parameter for assessing the impact of light on duckweed growth. • There is no clearly defined preference for N source. • The ratio of N:P has important effects on growth rates. [ABSTRACT FROM AUTHOR]

Published

2024

4. Constructed wetland for wastewater reuse: Role and efficiency in removing enteric pathogens.

Author

Shingare, Rita P., Thawale, Prashant R., Raghunathan, Karthik, Mishra, Apurva, and Kumar, Sunil

Subjects

*CONSTRUCTED wetlands, *WATER reuse, *FRESH water, *PATHOGENIC microorganisms, *POPULATION, *WETLAND restoration

Abstract

Water stress has become a perennial concern in most of the developing countries due to rapid urbanization and population growth. As the growing population requires more fresh water and better ways for wastewater disposal, the demand for wastewater reclamation has increased drastically in recent years. Wastewater, either raw or treated, is being widely used for agricultural irrigation in developing countries, which cause a serious threat to human health mainly because of its pathogenic content. One of the alternative methods to treat wastewater and make it reusable for agricultural irrigation is to implement constructed wetland (CW); a sustainable and cost-effective technology that is applicable for the elimination of both pollutants and pathogens from wastewater. Despite its wide application, the role of macrophytes that form an integral part of CW and specific mechanisms involved in pathogen removal by them is still barely understood due to complexities involved and influencing factors. This has, therefore, attracted various scientific studies to reveal further functional mechanisms involved in vegetated CW to increase its proficiencies. This review paper illustrates the comparative studies of different CW and their pathogen removal efficiencies with major emphasis on macrophytes involved and factors influencing related mechanism. Further, the paper also covers detailed information on the enteric pathogens present in wastewater and the associated health risks involved in its reuse. The ultimate objective is to further clarify the role of CW in enteric pathogen removal and its efficiency for wastewater purification in perspective with safe reuse in agriculture. • Pathogen removal mechanism is radically influenced by wetland type and vegetation. • Higher enteric pathogen removal efficiency was obtained with hybrid CW. • Cryptosporidium , Giardia , helminths and human-virulent microsporidia can be used as indicators in parasites endemic areas. • Root exudates and related mechanisms are required to determine direct impact of macrophytes. [ABSTRACT FROM AUTHOR]

Published

2019

5. Oxygen micro-nanobubbles for mitigating eutrophication induced sediment pollution in freshwater bodies.

Author

Ali, Jafar, Yang, Yuesuo, and Pan, Gang

Subjects

*HYPOXIA (Water), *WATER pollution, *SEDIMENTS, *BIOGEOCHEMICAL cycles, *MICROBIAL remediation, *RESTORATION ecology, *EUTROPHICATION, *AQUATIC biodiversity

Abstract

Sediment hypoxia is a growing problem and has negative ecological impacts on the aquatic ecosystem. Hypoxia can disturb the biodiversity and biogeochemical cycles of both phosphorus (P) and nitrogen (N) in water columns and sediments. Anthropogenic eutrophication and internal nutrient release from lakebed sediment accelerate hypoxia to form a dead zone. Thus, sediment hypoxia mitigation is necessary for ecological restoration and sustainable development. Conventional aeration practices to control sediment hypoxia, are not effective due to high cost, sediment disturbance and less sustainability. Owing to high solubility and stability, micro-nanobubbles (MNBs) offer several advantages over conventional water and wastewater treatment practices. Clay loaded oxygen micro-nanobubbles (OMNBs) can be delivered into deep water sediment by gravity and settling. Nanobubble technology provides a promising route for cost-effective oxygen delivery in large natural water systems. OMNBs also have the immense potential to manipulate biochemical pathways and microbial processes for remediating sediment pollution in natural waters. This review article aims to analyze recent trends employing OMNBs loaded materials to mitigate sediment hypoxia and subsequent pollution. The first part of the review highlights various minerals/materials used for the delivery of OMNBs into benthic sediments of freshwater bodies. Release of OMNBs at hypoxic sediment water interphase (SWI) can provide significant dissolved oxygen (DO) to remediate hypoxia induced sediment pollution Second part of the manuscript unveils the impacts of OMNBs on sediment pollutants (e.g., methylmercury, arsenic, and greenhouse gases) remediation and microbial processes for improved biogeochemical cycles. The review article will facilitate environmental engineers and ecologists to control sediment pollution along with ecological restoration. [Display omitted] • OMNBs can mitigate eutrophication induced anoxia and sediment pollution. • Cost-effective technology for environmental remediation and ecological restoration. • Positive influence of OMNBs on microbial processes and geochemical cycle. • Reduced emission of GHGs and sustainable restoration of aquatic biodiversity. [ABSTRACT FROM AUTHOR]

Published

2023

6. Evaluation of clay aggregate biotrickling filters for treatment of gaseous emissions from intensive pig production.

Author

Liu, Dezhao, Løkke, Mette Marie, Leegaard Riis, Anders, Mortensen, Knud, and Feilberg, Anders

Subjects

*LIVESTOCK housing, *AIR filters, *LIVESTOCK housing -- Heating & ventilation, *CLAY, *METHANETHIOL, *OXIDATION of hydrogen sulfide, *AMMONIA, *BIOFILTRATION, *ODOR control

Abstract

Treatment of ventilation air from livestock production by biological airfiltration has emerged as a cost-effective technology for reduction of emissions of odorants and ammonia. Volatile sulfur compounds from livestock production include H2S and methanethiol, which have been identified as potentially important odorants that are not removed sufficiently by biological air filters. Light-expanded clay aggregates (Leca®) is a biotrickling filter material that contains iron oxides, which can oxidize H2S and methanethiol, and thus potentially may help to remove these two compounds in biological air filters. This study used on-line PTR-MS measurements to investigate the performances of two Leca® biotrickling filters (abraded Leca® filter and untreated Leca® filter) for removal of odorants and ammonia emitted from an experimental pig house. The results indicated that the abraded Leca® filter had a similar or slightly better capability for removing odorants than the untreated Leca® filter. This may be due to the enlargement of the surface area by the friction process. The volatile sulfur compounds, however, were not removed efficiently by either of the two Leca® filters. Kinetic analysis of a ventilation controlled experiment during the first period indicated that Grau second-order kinetics could be applied to analyze the removal of sulfur compounds and other odorants, whereas the Stover-Kincannon model could only be applied to analyze the removal of odorants other than sulfur compounds, partly due to the limitation of mass transfer of these compounds in the biotrickling filters. In the last measurement period, a production of dimethyl disulfide and dimethyltrisulfide coinciding with strongly enhanced removal of methanethiol was observed for the untreated filter. This was assumed to be enhanced by an incidence of low local air velocity in the filter and indicated involvement of iron-catalyzed reactions in the removal of sulfur compounds. [Copyright &y& Elsevier]

Published

2014

7. Application of membrane bioreactor technology for wastewater treatment and reuse in the Mediterranean region: Focusing on removal efficiency of non-conventional pollutants

Author

Bolzonella, David, Fatone, Francesco, di Fabio, Silvia, and Cecchi, Franco

Subjects

*MEMBRANE separation, *BIOREACTOR research, *EFFICIENCY of sewage disposal plants, *WATER reuse, *ACTIVATED sludge process, *POLLUTANTS, *INDUSTRIAL waste research, *ESCHERICHIA coli, *COST effectiveness

Abstract

The Mediterranean Region is a semi-arid area whose land is facing serious erosion, causing adverse impacts on agriculture. To improve the water availability, researchers have proposed the reclamation and reuse of treated wastewater. In this paper, we report the main findings of 10 years of research on the efficiencies of a conventional activated sludge process and a submerged membrane bioreactor, with particular emphasis on the removal of non-conventional pollutants. The studies showed that the membrane bioreactor produced a virtually solids-free, high-quality permeate: most nutrients, heavy metals, and persistent organic pollutants were removed, and in particular, dioxins, furans, and polychlorinated biphenyls were typically present at concentrations below the detection limit. Moreover, the total coliforms count decreased by 4–5log and Escherichia coli was absent from the membrane bioreactor permeate. These results, combined with the continuing reduction of the capital and operating costs for this approach, suggest that membrane bioreactors are an increasingly cost-effective technology to produce treated effluents that are suitable for reuse. [Copyright &y& Elsevier]

Published

2010

8. Bioleaching of heavy metals from sewage sludge: A review

Author

Pathak, Ashish, Dastidar, M.G., and Sreekrishnan, T.R.

Subjects

*SEWAGE sludge as fertilizer, *HEAVY metals, *SEWAGE sludge, *BACTERIAL leaching, *COST effectiveness, *WASTEWATER treatment, *LEACHATE

Abstract

During the treatment of sewage, a huge volume of sludge is generated, which is disposed of on land as soil fertilizer/conditioner due to the presence of nitrogen, phosphorus, potassium and other nutrients. However, the presence of toxic heavy metals and other toxic compounds in the sludge restricts its use as a fertilizer. Over the years, bioleaching has been developed as an environmentally friendly and cost-effective technology for the removal of heavy metals from the sludge. The present paper gives an overview of the various bioleaching studies carried out in different modes of operation. The various important aspects such as pathogen destruction, odor reduction and metal recovery from acidic leachate also have been discussed. Further, a detailed discussion was made on the various technical problems associated with the bioleaching process, which need to be addressed while developing the process on a larger scale. [Copyright &y& Elsevier]

Published

2009

9. Modelling soil salinity effects on salt water uptake and crop growth using a modified denitrification-decomposition model: A phytoremediation approach.

Author

Hussain Shah, Syed Hamid, Wang, Junye, Hao, Xiying, and Thomas, Ben W.

Subjects

*SOIL salinity, *SALINE waters, *CROP growth, *SALT-tolerant crops, *PHYTOREMEDIATION, *ENERGY crops, *WHEAT, *PLANT transpiration

Abstract

Soil salinization is a widespread problem affecting global food production. Phytoremediation is emerging as a viable and cost-effective technology to reclaim salt-affected soil. However, its efficiency is not clear due to the uncertainty of plant responses in saline soils. The main objective of this paper is to propose a phytoremediation dynamic model (PDM) for salt-affected soil within the process-based biogeochemical denitrification-decomposition (DNDC) model. The PDM represents two salinity processes of phytoremediation: plant salt uptake and salt-affected biomass growth. The salt-soil-plant interaction is simulated as a coupled mass balance equation of water and salt plant uptake. The salt extraction ability by plant is a combination of salt uptake efficiency (F) and transpiration rate. For water filled pore space (WFPS) , the statistical measures RMSE , MAE , and R 2 during the calibration period are 2.57, 2.14, and 0.49, and they are 2.67, 2.34, and 0.56 during the validation period, respectively. For soil salinity, RMSE , MAE , and R 2 during the calibration period are 0.02, 0.02, and 0.92, and 0.06, 0.04, and 0.68 during the validation period, respectively, which are reasonably good for further scenario analysis. Over the four years, cumulative salt uptake varied based on weather conditions. At the optimal salt uptake efficiency (F = 20), cumulative salt uptake from soil was 16–90% for alfalfa, 11–70% for barley, and 10–80% for spring wheat. While at the lowest salt uptake efficiency (F = 40), cumulative salt uptake was nearly zero for all crops. Although barley has the highest peak transpiration flux, alfalfa and spring wheat have greater cumulative salt uptake because their peak transpiration fluxes occurred more frequently than in barley. For salt-tolerant crops biomass growth depends on their threshold soil salinity which determines their ability to take up salt without affecting biomass growth. In order to phytoremediate salt-affected soil, salt-tolerant crops having longer duration of crop physiological stages should be used, but their phytoremediation effectiveness will depend on weather conditions and the soil environment. [Display omitted] • Salt-soil-plant interaction is simulated in denitrification-decomposition model. • Salt uptake is complex function of transpiration flux, soil moisture and salinity. • The cumulative salt uptake in barley is smaller than alfalfa and spring wheat. • Biomass growth of alfalfa is smaller than spring wheat and barley in saline soil. • The longer crop physiological stages is a key for efficient phytoremediation. [ABSTRACT FROM AUTHOR]

Published

2022

10. Watershed-based point sources permitting strategy and dynamic permit-trading analysis

Author

Ning, Shu-Kuang and Chang, Ni-Bin

Subjects

*TOTAL maximum daily load for water pollutants, *SPATIO-temporal variation, *LICENSES, *NUTRIENT trading, *BIOCHEMICAL oxygen demand, *EMISSIONS trading, *WATERSHEDS, *WATER quality management

Abstract

Permit-trading policy in a total maximum daily load (TMDL) program may provide an additional avenue to produce environmental benefit, which closely approximates what would be achieved through a command and control approach, with relatively lower costs. One of the important considerations that might affect the effective trading mechanism is to determine the dynamic transaction prices and trading ratios in response to seasonal changes of assimilative capacity in the river. Advanced studies associated with multi-temporal spatially varied trading ratios among point sources to manage water pollution hold considerable potential for industries and policy makers alike. This paper aims to present an integrated simulation and optimization analysis for generating spatially varied trading ratios and evaluating seasonal transaction prices accordingly. It is designed to configure a permit-trading structure basin-wide and provide decision makers with a wealth of cost-effective, technology-oriented, risk-informed, and community-based management strategies. The case study, seamlessly integrating a QUAL2E simulation model with an optimal waste load allocation (WLA) scheme in a designated TMDL study area, helps understand the complexity of varying environmental resources values over space and time. The pollutants of concern in this region, which are eligible for trading, mainly include both biochemical oxygen demand (BOD) and ammonia-nitrogen (NH3-N). The problem solution, as a consequence, suggests an array of waste load reduction targets in a well-defined WLA scheme and exhibits a dynamic permit-trading framework among different sub-watersheds in the study area. Research findings gained in this paper may extend to any transferable dynamic-discharge permit (TDDP) program worldwide. [Copyright &y& Elsevier]

Published

2007

11. Recycling of sugar crop disposal to boost the adaptation of canola (Brassica napus L.) to abiotic stress through different climate zones.

Author

Kheir, Ahmed M.S., Ali, Esmat F., He, Zhenli, Ali, Osama A.M., Feike, Til, Kamara, Mohamed M., Ahmed, Mukhtar, Eissa, Mamdouh A., Fahmy, Ahmed E., and Ding, Zheli

Subjects

*SUGAR crops, *RAPESEED, *ABIOTIC stress, *CANOLA, *SOIL productivity, *SUSTAINABLE agriculture, *SUGAR beets

Abstract

We need to produce higher foods even under declining natural resources to feed the projected population of 9 billion by 2050 and to sustain food security and nutrition. Abiotic stress has adversely affected canola crop and oil quality especially in sandy soils. To combat this stress, adaptation at the farm level using new and cost-effective amendments are required. Field trials were conducted in two different climatic zones to determine the efficacy of cane molasses, bagasse ash, sugar beet factory lime, and their compost mixtures to improve soil quality and heat stress-adapting canola. The results showed a significant improvement in bulk density, hydraulic conductivity, organic matter content, and available macronutrients of sandy soil and subsequent canola growth, yield, quality and water productivity due to the application of the tested soil amendments, particularly those mixed with compost. Despite the estimated reduction of yield by 18.5% due to heat stress, application of sugar beet lime and compost mixture not only compensated for this reduction but also increased the seed yield by 27.0%. These findings highlight the value of recycling compost-based sugar crop disposal as a cost-effective technology to boost crop tolerance to abiotic stress, ensuring sustainable agriculture and food security in arid environments. • Abiotic stress is a common problem facing dry and semi-arid agriculture. • Warming induced reduction in soil moisture affects soil fertility. • Water shortages and rising temperatures need better on-field management. • Sugar factory disposals with compost improved soil traits and canola yield. • Adding SBFLC and CMC has mitigated temperature impacts and improved crop yields. [ABSTRACT FROM AUTHOR]

Published

2021

12. Potential of constructed wetland treatment systems for agricultural wastewater reuse under the EU framework.

Author

Nan, Xi, Lavrnić, Stevo, and Toscano, Attilio

Subjects

*CONSTRUCTED wetlands, *GRAYWATER (Domestic wastewater), *TOTAL suspended solids, *BIOCHEMICAL oxygen demand, *WASTEWATER treatment, *EFFLUENT quality

Abstract

One of the solutions for the problems regarding increasing water scarcity and pollution of water resources can be wastewater reuse. Constructed wetlands (CWs) are a sustainable and cost-effective technology for wastewater treatment. If they are able to produce effluent of a needed quality, they can be a valuable addition for wastewater reuse schemes. This review studied 39 treatment systems based on CWs, and it assessed their characteristics and performance on pollutant removal. Moreover, their potential to reach the new European Union standards for agricultural wastewater reuse was evaluated. The results showed that the combination of CWs with additional technologies (e.g. UV treatment, anaerobic reactors) can further increase their performance and provide better removal efficiencies in comparison with conventional horizontal and vertical subsurface flow CWs. Particularly, hybrid systems showed a better removal of organic matter and bacterial indicators than single-stage CWs. For most of the systems considered, the concentrations of biochemical oxygen demand and total suspended solids in treated effluent were below the limits for agricultural reuse. However, that was often not the case with Escherichia coli and therefore it is recommended to add a disinfection unit to the systems in order to achieve the levels required in the case of agricultural reuse. • Additional technologies increase performance of conventional constructed wetlands. • The multistage treatment systems can optimize overall removal efficiency. • Seasonal variations and substrate types can affect pollutant removal. • Effluent disinfection is recommended for wastewater reuse application. [ABSTRACT FROM AUTHOR]

Published

2020