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Academic Journal of Environmental Biology, 2021, 2(2); doi: 10.38007/AJEB.2021.020201.

Fuzzy Comprehensive Evaluation of Qinghe Water Environment Based on Biometric Index of Macrobenthos Community Biological Index

Author(s)

Lotfifard Saeed

Corresponding Author:
Lotfifard Saeed
Affiliation(s)

Ben Gurion Univ Negev, Beer Sheva, Israel

Abstract

With the rapid improvement of my country's industrialization process, the unreasonable use of water resources, deforestation, vegetation destruction and other phenomena frequently occur, especially the poor public awareness of environmental protection, lack of awareness of the protection of water resources in the Qinghe River, etc. Decline. Studying the Qinghe water environment based on the macrobenthos community biological index can provide a strong scientific basis for the management of the Qinghe water environment. The purpose of this paper is to comprehensively evaluate the water environment of Qinghe River based on the biometric index of macrobenthos community. During the experiment, samples were collected and analyzed for the sample collection method, namely direct hand net sampling in shallow rivers and foot manipulation in deeper water. Using the BI index method, the spatial distribution of macrobenthos species and the fuzzy comprehensive health assessment of the Qinghe water environment were investigated and analyzed.

Keywords

Macrobenthos, Community Biological Index, Water Environment of Qinghe River, Fuzzy Comprehensive Evaluation

Cite This Paper

Lotfifard Saeed. Fuzzy Comprehensive Evaluation of Qinghe Water Environment Based on Biometric Index of Macrobenthos Community Biological Index. Academic Journal of Environmental Biology (2021), Vol. 2, Issue 2: 1-11. https://doi.org/10.38007/AJEB.2021.020201.

References

[1] Likai, NIE. Review of Effects of Macrobenthos Bioturbation on Sediment Biogeochemical Cycle. Agricultural Biotechnology, 2020, 9(02):90-92.

[2] Martin J P, Sar A, Caminos C . Spatial changes in the infaunal community of a macrotidal flat in Bahía San Julián, Southern Patagonia, Argentina. Revista de Biologia Marina Y Oceanografia, 2019, 54(1):51-51. https://doi.org/10.22370/rbmo.2019.54.1.1494

[3] Losi V, Sbrocca C, Gatti G, et al. Sessile macrobenthos (Ochrophyta) drives seasonal change of meiofaunal community structure on temperate rocky reefs. Marine Environmental Research, 2018, 142(11):295-305. https://doi.org/10.1016/j.marenvres.2018.10.016

[4] Amfa M O, Abdurrahman M I, Hidayat S A, et al. Macrobenthos community structure in coral reef ecosystem around Pramuka Island, Jakarta. IOP Conference Series Earth and Environmental Science, 2020, 420(1):012003-012003.

[5] Syakur A, Paembonan S . Inventory of macrozoobenthos community in Mangrove Ecosystem, Labombo Beach, Palopo, South Sulawesi. Journal of Physics Conference Series, 2021, 1940(1):012059-012059.

[6] Gerasimova A V, Filippova N A, Lisitsyna K N, et al. Current state of macrobenthos in the southwestern Kara Sea. Continental Shelf Research, 2021, 224(74):104452-104452. https://doi.org/10.1016/j.csr.2021.104452

[7] Syakur A, Paembonan S . Inventory of macrozoobenthos community in Mangrove Ecosystem, Labombo Beach, Palopo, South Sulawesi. Journal of Physics Conference Series, 2021, 1940(1):012059.

[8] B Y L A, A L S, A Y T, et al. Influence of two non-indigenous plants on intertidal macrobenthic communities in Ximen Island Special Marine Protected Area, China. Ecological Engineering, 2018, 112(1):96-104. https://doi.org/10.1016/j.ecoleng.2017.12.023

[9] Meena D K, Lianthuamluaia L, Mishal P, et al. Assemblage patterns and community structure of macro-zoobenthos and temporal dynamics of eco-physiological indices of two wetlands, in lower gangetic plains under varying ecological regimes: A tool for wetland management. Ecological Engineering, 2019, 130(1):1-10. https://doi.org/10.1016/j.ecoleng.2019.02.002

[10] Bagley M, Pilgrim E, Knapp M, et al. High-throughput environmental DNA analysis informs a biological assessment of an urban stream. Ecological Indicators, 2019, 104(9):378-389.

[11] Ramalho S P, Almeida M, Esquete P, et al. Bottom-trawling fisheries influence on standing stocks, composition, diversity and trophic redundancy of macrofaunal assemblages from the West Iberian Margin. Deep Sea Research Part I: Oceanographic Research Papers, 2018, 138(8):131-145. https://doi.org/10.1016/j.dsr.2018.06.004

[12] Ginebreda A . Emerging contaminants and nanoplastics in the water environment: a matter of rising concern. Water Emerging Contaminants & Nanoplastics, 2021, 1(1):1-1. https://doi.org/10.20517/wecn.2021.02

[13] N'Doye I, Zhang D, Alouini M S, et al. Establishing and Maintaining a Reliable Optical Wireless Communication in Underwater Environment. IEEE Access, 2021, 99(99):1-1.

[14] A M T, A J S, B D B, et al. Laser-assisted surface modification of Ti-implant in air and water environment. Applied Surface Science, 2018, 428(1):669-675. https://doi.org/10.1016/j.apsusc.2017.09.185

[15] Konovalov R S, Konovalov S I, Kuz'Menko A G, et al. Forming a short acoustic signal to study the underwater environment. Journal of Physics: Conference Series, 2021, 1991(1):01202-01203.

[16] Sima M W, PR Jaffé. A critical review of modeling Poly- and Perfluoroalkyl Substances (PFAS) in the soil-water environment. Science of The Total Environment, 2020, 757(12):143793-143793.

[17] Chen Q, Chamoli S K, Yin P, et al. Active mode single pixel imaging in the highly turbid water environment using compressive sensing. IEEE Access, 2019, 99(99):1-1. https://doi.org/10.1109/ACCESS.2018.2875722

[18] Cuicui, Li, Weiying, et al. Three decades of changes in water environment of a large freshwater Lake and its relationship with socio-economic indicators. Journal of Environmental Sciences, 2019, 77(03):159-169. https://doi.org/10.1016/j.jes.2018.07.001