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Effectiveness of aquatic plants in reducing water nitrates | ||
Caspian Journal of Environmental Sciences | ||
دوره 20، شماره 5، اسفند 2022، صفحه 1031-1037 اصل مقاله (818.11 K) | ||
نوع مقاله: Research Paper | ||
شناسه دیجیتال (DOI): 10.22124/cjes.2022.6066 | ||
نویسندگان | ||
Thair Aljawahiry* 1؛ Ahmed Hasoon2؛ Ahmed Falah Imran3؛ Aliaa Kareem Abdulla4؛ Mahmood Al-Mualm5؛ Saba Naseer Abbas6 | ||
1College of Pharmacy, Ahl Al Bayt University, Kerbala, Iraq | ||
2Engineering Technical College, Al-Farahidi University, Baghdad, Iraq | ||
3Department of Anesthesia, Hilla University College, Iraq | ||
4Pharmacy Department, Al-Mustaqbal University College, Babylon, Iraq | ||
5Department of Medical Laboratories Technology, AL-Nisour University College, Baghdad, Iraq | ||
6Al-Esraa University College, Baghdad, Iraq | ||
چکیده | ||
Due to the lack of fresh water, the purification of polluted water is of utmost importance and places a significant financial burden on countries. The effect of Myriophyllum spicatum and Lemna gibba on nitrate absorption in an area of the Tigris River has been investigated in the light of the low cost and ease of application of aquatic plants in purifying water pollution. Aquarium experiments were designed with three treatments, three replicates, and a closed flow. In the aquarium, the biological requirements for the growth of the studied plants were met. The residence time was determined to be 36 days, and nitrate changes were recorded every three days, 12 times. Except for periods 3 and 4, there were significant differences in the rate of nitrate absorption between the studied plants in all treatments (P < 0.05). At the end of the 12th period, M. spicatum and L. gibba had contaminant removal efficiency of 83.31% and 86.27%, respectively. L. gibba ability to utilize nitrate as a nutrient was demonstrated by its significantly increased dry weight at the end of the experiment (P < 0.05). In the current study, the significant difference between the average levels of nitrate in the samples and the control sample indicates the presence of a factor other than bacterial decomposition, namely the presence of plants. According to the findings, these macrophytes are viable for reducing nitrate and organic matter loads in polluted waters. Controlling these macrophytes, so that the nutrients in their tissues do not return to the environment during decomposition is necessary to improve water quality and maintain the achieved quality. | ||
کلیدواژهها | ||
Nitrate؛ Myriophyllum spicatum؛ Lemna gibba؛ Contaminant removal | ||
مراجع | ||
Ameri Siahouei, R, Zaeimdar, M, Moogouei, R & Jozi, SA 2020, Potential of Cyperus alternifolius, Amaranthus retroflexus, Closia cristata and Bambusa vulgaris to phytoremediate emerging contaminants and phytodesalination; Insight to floating beds technology. Caspian Journal of Environmental Sciences, 18: 309-317.
Chen, X, Lu, J, Zhu, J & Liu, C 2020, Characteristics of denitrifying bacteria in different habitats of the Yongding River wetland, China. Journal of Environmental Management, 275: 111273.
Ciji, A & Akhtar, MS 2020, Nitrite implications and its management strategies in aquaculture: A review. Reviews in Aquaculture, 12: 878-908.
Dey, S, Uppala, P, Sambangi, A, Haripavan, N & Veerendra, GTN 2022, Recycling of solid waste biosorbents for removal of nitrates from contaminated water. Cleaner and Circular Bioeconomy, 2: 100014.
Egbi, CD, Anornu, GK, Ganyaglo, SY, Appiah Adjei, EK, Li, SL & Dampare, SB 2020, Nitrate contamination of groundwater in the Lower Volta River Basin of Ghana: sources and related human health risks. Ecotoxicology and Environmental Safety, 191: 110227.
Ergönül, MB, Nassouhi, D, Çelik, M & Atasağun, S 2021, A comparison of the removal efficiencies of Myriophyllum spicatum L. for zinc oxide nanoparticles (ZnO NP) in different media: a microcosm approach. Environmental Science and Pollution Research, 28: 8556-8568.
Eribo, O, Enodiana, O & Aghayevbe, O 2019, Utilization of Lemna paucicostata for Low-cost Removal of Contaminants from Beverage Factory Effluent. African Scientist, 18: 239-244.
Gecheva, GM, Yordanov, ES & Stankova, SY 2022, Macrophytes in the Veleka River, Bulgaria: Species Diversity and Assessment of the Ecological Status. Ecologia Balkanica.
Gomez Isaza, DF, Cramp, RL & Franklin, CE 2020, Simultaneous exposure to nitrate and low pH reduces the blood oxygen-carrying capacity and functional performance of a freshwater fish. Conservation physiology, 8: coz092.
Isaza, DFG, Cramp, RL & Franklin, CE 2020, Living in polluted waters: A meta-analysis of the effects of nitrate and interactions with other environmental stressors on freshwater taxa. Environmental Pollution, 261: 114091.
Isiuku, BO & Enyoh, CE 2020, Pollution and health risks assessment of nitrate and phosphate concentrations in water bodies in South Eastern, Nigeria. Environmental Advances, 2: 100018.
Jungers, JM, DeHaan, LH, Mulla, DJ, Sheaffer, CC & Wyse, DL 2019, Reduced nitrate leaching in a perennial grain crop compared to maize in the Upper Midwest, USA. Agriculture, Ecosystems & Environment, 272: 63-73.
Kareem, NA & Kadhim, NF 2021, Biochemical responses of some aquatic plants as indicators for the treatment of inorganic nitrogen compounds in wastewater (Case study: Domestic water treatment plant in Babil Governorate, Iraq). Caspian Journal of Environmental Sciences, 19: 1035-1044.
Kumar, S, Thakur, N, Singh, AK, Gudade, BA, Ghimire, D & Das, S 2022, Aquatic macrophytes for environmental pollution control: Phytoremediation Technology for the Removal of Heavy Metals and Other Contaminants from Soil and Water, Elsevier, pp. 291-308.
Li, D, Wang, T, Li, Z, Xu, X, Wang, C & Duan, Y 2019, Application of graphene-based materials for detection of nitrate and nitrite in water—a review. Sensors, 20: 54.
Luo, G, Xu, J & Meng, H 2020, Nitrate accumulation in biofloc aquaculture systems. Aquaculture, 520, 734675.
Mahmud, MP, Ejeian, F, Azadi, S, Myers, M, Pejcic, B, Abbassi, R & Asadnia, M 2020, Recent progress in sensing nitrate, nitrite, phosphate, and ammonium in aquatic environment. Chemosphere, 259: 127492.
Manikandan, V, Jayanthi, P, Priyadharsan, A, Vijayaprathap, E, Anbarasan, P & Velmurugan, P 2019, Green synthesis of pH-responsive Al2O3 nanoparticles: Application to rapid removal of nitrate ions with enhanced antibacterial activity. Journal of Photochemistry and Photobiology A: Chemistry, 371: 205-215.
Misra, S & Misra, KG 2019, Phytoremediation: an alternative tool towards clean and green environment: Sustainable green technologies for environmental management, Springer, pp. 87-109.
Mushtaq, N, Singh, DV, Bhat, RA, Dervash, MA & Hameed, Ob 2020, Freshwater contamination: Sources and hazards to aquatic biota. Fresh Water Pollution Dynamics and Remediation. Springer, pp. 27-50.
Mustafa, HM & Hayder, G 2021, Recent studies on applications of aquatic weed plants in phytoremediation of wastewater: A review article. Ain Shams Engineering Journal, 12: 355-365.
Omidi, A & Shariati, F 2021, Evaluation of Pasikhan River, north of Iran using water quality index (NSFWQI). Caspian Journal of Environmental Sciences, 19: 219-230.
Priya, E, Kumar, S, Verma, C, Sarkar, S & Maji, PK 2022, A comprehensive review on technological advances of adsorption for removing nitrate and phosphate from waste water. Journal of Water Process Engineering, 49: 103159.
Sathishkumar, K, Li, Y & Sanganyado, E 2020, Electrochemical behavior of biochar and its effects on microbial nitrate reduction: role of extracellular polymeric substances in extracellular electron transfer. Chemical Engineering Journal, 395: 125077.
Szalińska, E, Orlińska Woźniak, P & Wilk, P 2018, Nitrate vulnerable zones revision in Poland—Assessment of environmental impact and land use conflicts. Sustainability, 10: 3297.
Thapa, R, Mirsky, SB & Tully, KL 2018, Cover crops reduce nitrate leaching in agroecosystems: A global meta‐analysis. Journal of environmental quality, 47: 1400-1411.
Töre, GY & Özkoç, ÖB 2022, Recent developments in aquatic macrophytes for environmental pollution control: A case study on heavy metal removal from lake water and agricultural return wastewater with the use of duckweed (Lemnacea): Phytoremediation Technology for the Removal of Heavy Metals and Other Contaminants from Soil and Water. Elsevier, pp. 75-127.
Valenca, R, Le, H, Zu, Y, Dittrich, TM, Tsang, DC, Datta, R & Mohanty, SK 2021, Nitrate removal uncertainty in stormwater control measures: Is the design or climate a culprit? Water Research, 190: 116781.
Wang, S, Liu, C, Wang, X, Yuan, D & Zhu, G 2020, Dissimilatory nitrate reduction to ammonium (DNRA) in traditional municipal wastewater treatment plants in China: Widespread but low contribution. Water Research, 179: 115877.
Wang, S, Pi, Y, Song, Y, Jiang, Y, Zhou, L, Liu, W & Zhu, G 2020, Hotspot of dissimilatory nitrate reduction to ammonium (DNRA) process in freshwater sediments of riparian zones. Water Research, 173: 115539.
Wickramasinghe, S & Jayawardana, CK 2018, Potential of aquatic macrophytes Eichhornia crassipes, Pistia stratiotes and Salvinia molesta in phytoremediation of textile wastewater. Journal of water security, 4.
Yun, L, Yu, Z, Li, Y, Luo, P, Jiang, X, Tian, Y & Ding, X 2019, Ammonia nitrogen and nitrite removal by a heterotrophic Sphingomonas sp. strain LPN080 and its potential application in aquaculture. Aquaculture, 500: 477-484.
Zhang, Y, Shi, P, Song, J & Li, Q 2018, Application of nitrogen and oxygen isotopes for source and fate identification of nitrate pollution in surface water: a review. Applied Sciences, 9: 18.
Zhu, T, Chen, Q, Liao, P, Duan, W, Liang, S, Yan, Z & Feng, C 2020, Single‐Atom Cu Catalysts for Enhanced Electrocatalytic Nitrate Reduction with Significant Alleviation of Nitrite Production. Small, 16: 2004526.
Zuo, X, Zhang, H & Yu, J 2020, Microbial diversity for the improvement of nitrogen removal in stormwater bioretention cells with three aquatic plants. Chemosphere, 244: 125626. | ||
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