Opportunities for Treatment and Reuse of Agricultural Drainage in the United States

Hejase, Charifa A.; Weitzel, Katelin A.; Grauberger, Brandi M.; Young, Robert B.; Arias‐Paić, Miguel; Kong, Minghao; Chae, Soryong; Bandhauer, Todd M.; Tong, Tiezheng; Herber, Daniel R.; Stout, Sherry; Miara, Ariel; Huang, Zuhao; Evans, Anna; Kurup, Parthiv; Talmadge, Michael; Kandt, Alicen; Stokes-Draut, Jennifer; Macknick, Jordan; Dionysiou, Dionysios D.

doi:10.1021/acsestengg.1c00277

Cited by 17 publications

(14 citation statements)

References 73 publications

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“…ADW is the largest volume of agricultural wastewater. It contains valuable nutrients (nitrate and phosphate), excess salts and other toxicants [2]. Discharge of saline drainage water into natural water bodies reduces water quality, crop yields and soil microbial diversity.…”

Section: Introductionmentioning

confidence: 99%

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Sulphate Minimization in Agricultural Drainage Water Using Modified Rice Husk

Adejumobi

Adebayo

Onofua

2022

AIR

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Eutrophication, salinization, hypoxia, and toxic algae, among other environmental damages are costly consequences of agricultural drainage water (ADW), and therefore poses a threat to ecological biodiversity, food security and agriculture sustainability. This work aimed to assess the adsorption efficiency of rice husk (RH) modified by chemical and thermal treatments for sulphate minimization from ADW. RH obtained from a local rice mill was washed in distilled water, oven-dried at 105 ˚C for 24 h, milled and sieved into 0.3–1.18 mm particle sizes. The optimum condition for carbonization was determined by varying the temperature- 200, 300 and 400 ˚C and time- 1, 1.5, and 2 h, respectively. The RH was activated by chemical (H3PO4 and ZnCl2) and thermal treatment. Batch experiments were carried out varying temperature (40-60 °C), adsorption time (15–140 min) and adsorbent dose (1 and 2 g) in an ADW with known sulphate concentration, 30 mg/L. The carbonization yield at 400, 300 and 200 ˚C varies within 18.91- 27.48%, 27.39- 32.82 % and 81.94- 95.75% respectively. It was observed that the percentage of carbon converted into silica increases with burning time; hence, the optimum temperature of 350 ˚C for 2 h was used for carbonization. Also, sulphate adsorption rate increased with contact time and dosage suggesting that the process is controlled by surface and pore diffusion. Based on the temperature study, adsorption was favourable at lower temperatures. H3PO4 and ZnCl2 treated adsorbents have similar removal efficiency; however, ZnCl2 treated adsorbent has a higher efficiency due to its ability to enhance the stability and mesoporosity of carbonaceous material. Modified RH is a potential adsorbent that could be of noble use in ADW quality minimization. However, the huge gap between literature studies and field application needs to be bridged by good extension services and appropriate policy.

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Section: Introductionmentioning

confidence: 99%

“…This water can be captured and reused via cycling or blending as irrigation water [4]. Treatment and reuse of ADW is essential to meet the rising demand for water in agriculture and prevent environmental damages such as soil salinization, eutrophication, and other environmental pollution [2].…”

Section: Introductionmentioning

confidence: 99%

Sulphate Minimization in Agricultural Drainage Water Using Modified Rice Husk

Adejumobi

Adebayo

Onofua

2022

AIR

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“…After the completion of the hydraulic fracturing stage in shale gas operations, wastewater mainly returns to the surface as flowback water (the initial water that is recovered with shale gas) and produced water mostly comprising the natural deep formation water. − Therefore, FPW usually contains high concentrations of total dissolved solids (TDS), organic matter (dissolved organic carbon; DOC), metals, hydrocarbons and other volatile compounds, some synthetic organic chemical additives, as well as some naturally occurring radioactive materials that may be present in the formation. − In recent years, the option of applying FPW directly or indirectly for agricultural irrigation has become a focus of growing discussion. , Small amounts of organic matter and micronutrient elements in municipal sewage and industrial wastewaters, at times also including rare earth elements (e.g., Ce), have been shown to promote the growth of some algae strains or higher plants under certain circumstances. − On the other hand, the salinity, alkalinity, and ionic composition of oilfield-produced water may significantly hinder its reuse in agriculture since these characteristics can cause nutrient imbalances, as well as osmotic and specific ion stress, in plant cells. , Methods of reusing produced water with minimal TDS treatment or upon dilution with freshwater for farmland irrigation are currently being applied in Kern County (California), but the complexity of FPW components can result in detrimental effects on humans and ecosystems …”

Section: Introductionmentioning

confidence: 99%

Safety and Technical Feasibility of Sustainable Reuse of Shale Gas Flowback and Produced Water after Advanced Treatment Aimed at Wheat Irrigation

Yang

Tian

Tariq

et al. 2022

ACS Sustainable Chem. Eng.

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Treatment and reuse of flowback and produced water (FPW) from shale gas extraction for agricultural irrigation has often been proposed as a sustainable alternative to disposal via deep-well injection. Here, we investigate the effects of FPW on the germination period, macroscopic growth, element enrichment, and grain gene expression of wheat upon dilution and advanced membrane treatment of the liquid stream. Compared to tap water, irrigation with treated FPW shortened the germination time, slightly improved the seed vigor index, and ensured a similar germination rate. On the other hand, the biomass and grain yield of mature wheat irrigated with treated FPW and with FPW diluted to 5% groups decreased compared to tests using tap water. After a whole growth cycle of wheat, higher concentrations of nutrients, such as K, Ca, and Mg were enriched in mature wheat tissue irrigated with treated FPW. However, the Pb and Cr contents of mature wheat grains treated with three types of irrigation waters exceeded the standard to varying degrees. A total of 1973 differentially expressed genes were mainly related to binding, catalytic activity, cellular process, metabolic process, and cell part, more than half of which were upregulated and induced by irrigation with treated FPW. These findings provide critical guidance for the reuse of treated shale gas FPW for agricultural application from the perspective of plant uptake of toxic elements, as well as crop and human health risks.

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“…Drainage water quality reflects the source water quality, soil water constituents and agricultural chemicals applied to the soil being drained [11]. Drainage water emanating from some regions are a nutrient source (N and P), making direct reuse on-site with minimal treatment feasible and enhancing a closed and environmentally favourable nutrient cycle [12]. In other regions, drainage water contains critical constituents affecting plant and soil conditions during longterm application, preventing reuse without treatment [13].…”

Section: Introductionmentioning

confidence: 99%

Quality Minimization of Agricultural Drainage Water for Irrigation Water Reuse Using Coconut Shell Activated Carbon

Adejumobi

Olaoye²,

Adebayo³

et al. 2022

ACRI

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Nutrients and organic pollutants draining from agricultural fields are the leading sources of surface water quality impairment. Activated carbon (AC) produced from agricultural crop residues has great success in the sequestration of hazardous substances from wastewaters. This study evaluates the potential of coconut shell activated carbon for agricultural drainage water quality minimization; pH adjustment, and excess nitrate and sulphate adsorption. Agriculture drainage water samples were collected and analyzed for Electrical conductivity, Total Dissolved Solids, Chloride, Sodium, Sulphate, Bicarbonate, Nitrate – Nitrogen, and pH. Coconut shells were sourced locally and carbonized at 500°C (± 5°C) for one hour in a muffle furnace. The char produced was ground, sieved, and activated with potassium hydroxide (KOH). The porosity and morphological structures of the AC were examined using a Scanning Electron Microscope. The effect of contact time (30, 60, 90, and 120 min), temperature (20 and 40°C), and adsorbent dosage (1, 1.5, 2, and 2.5 g) were examined using batch studies. The analysis of the drainage water shows the water is highly alkaline and contains sulphate and nitrate above FAO benchmark values. The SEM analysis indicates that the stability and mesoporosity of the carbonaceous material were enhanced by KOH activation. The pH value of the treated water decreased from 9.94 (highly alkaline) to 7.92. The use of 1 g (10 g/l) of coconut shell AC has the highest amount of nitrate and sulphate per unit quantity of AC (4.1 and 2.98 mg/g respectively). The adsorption process peaked at 30 mins contact time with 99.8% and 98.8% nitrate and sulphate removal efficiency, respectively. The process is temperature dependent; nitrate adsorption performs slightly better at 40°C; sulphate adsorption at 20°C. More research effort is needed to ascertain the performance and applicability under continuous flow conditions.

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Opportunities for Treatment and Reuse of Agricultural Drainage in the United States

Cited by 17 publications

References 73 publications

Sulphate Minimization in Agricultural Drainage Water Using Modified Rice Husk

Sulphate Minimization in Agricultural Drainage Water Using Modified Rice Husk

Safety and Technical Feasibility of Sustainable Reuse of Shale Gas Flowback and Produced Water after Advanced Treatment Aimed at Wheat Irrigation

Quality Minimization of Agricultural Drainage Water for Irrigation Water Reuse Using Coconut Shell Activated Carbon

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