Citation of: An aquatic ecosystem: a large-scale diversified bioreactor with a water self-purification function
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An aquatic ecosystem: a large-scale diversified bioreactor with a water self-purification function. (Ostroumov S.A.)
(2000) Doklady Biological Sciences, 374 (1-6) , pp. 514-516.
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#Citation: #aquatic #ecosystem: large-scale diversified bioreactor with a #water #self-purification #function. http://5bio5.blogspot.com/2013/05/citation-of-aquatic-ecosystem-large.html
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on the journal:
- Presents English translations of current Russian research as published in the Proceedings of the Russian Academy of Sciences
- Covers anatomy, cytology, ecology, embryology, endocrinology, evolutionary morphology, experimental morphology, genetic, histology, hydrobiology, immunology, microbiology, morphology, parasitology, physiology, virology, and zoology
Doklady Biological Sciences is a bimonthly journal presenting English translations of current Russian research in the anatomy, cytology, ecology, embryology, endocrinology, evolutionary morphology, experimental morphology, genetic, histology, hydrobiology, immunology, microbiology, morphology, parasitology, physiology, virology, and zoology sections of the Doklady Akademii Nauk (Proceedings of the Russian Academy of Sciences). The Proceedings appear 36 times per year; articles from the selected biological sections are collected, translated, and published bimonthly.
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This article was cited in the following publications, examples:
Examples of the names of the authors of the papers that cited this article:
Chen, Y.X.(1)
Li, H.(1)
Liang, X.Q.(1)
Liu, M.S.(1)
Ren, R.L.(1)
Widdows, J.(1)
Xu, L.(1)
Xu, M.(1)
Yao, Y.X.(1)
Zhang, J.M.(1)
Zhang, M.(1)
Zhang, X.Z.(1)
Zhou, L.(1)
Affiliations of these and other authors who cited this publication:
Plymouth Marine Laboratory, United Kingdom;
Moscow University, Russian Federation;
Affiliations of these and other authors who cited this publication:
Plymouth Marine Laboratory, United Kingdom;
Moscow University, Russian Federation;
Institute of Environmental Science and Technology, Zhejiang University, Hangzhou 310029, China
Key Laboratory for Water Pollution Control and Environmental Safety, Hangzhou 310029, Zhejiang Province, China
Environmental Monitoring Central Station, Huzhou 313000, China
Environmental Monitoring Station, Lanxi 321100, China
School of Life Science, Nanjing University, Nanjing 210093, China
Suqian Bureau of Forestry, Suqian 223800 Jiangsu, China
Environmental Conservation Bureau of Suqian, Suqian 223800 Jiangsu, China
Subject Areas:
Agricultural and Biological Sciences (5)
Environmental Science (4)
Earth and Planetary Sciences (2)
Cited by
1
Research on seasonal variation of self-purification ability for small shallow lakes in south lake Taihu
Xu, L., Li, H., Chen, Y.-X., Yao, Y.-X., Liang, X.-Q., Zhou, L., Zhang, X.-Z.
2010
Huanjing Kexue/Environmental Science 31 (4) , pp. 924-930.
Xu, L.a , Li, H.ab , Chen, Y.-X.ab, Yao, Y.-X.c, Liang, X.-Q.ab, Zhou, L.c, Zhang, X.-Z.ad
a Institute of Environmental Science and Technology, Zhejiang University, Hangzhou 310029, China
b Key Laboratory for Water Pollution Control and Environmental Safety, Hangzhou 310029, Zhejiang Province, China
c Environmental Monitoring Central Station, Huzhou 313000, China
d Environmental Monitoring Station, Lanxi 321100, China
View additional affiliations
View references (29)
Abstract
Seasonal variations of self-purification ability for small natural shallow lakes in South Lake Taihu were investigated. The results showed that seasonal difference of self-purification of permanganate index, total nitrogen (TN), ammonium (NH 4 +-N), nitrate (NO 3 --N), total phosphorus (TP), chlorophyll (Chl-a) in small shallow lakes were remarkable. Effects of self-purification were better in spring and winter, and were worse in summer by NH 4 +-N and NO 3 --N and in autumn by TP and Chl-a. Organic pollution was light, TN and TP pollution were seriously in four seasons. Concentrations of TN and TP brought a well condition to algae growth, and lakes were eutrification easily by the limiting factor of phosphorus. Concentrations of Chl-a were showed that lakes were eutrophic in summer or autumn and mesotrophic in winter or spring. Growth and blooms of phytoplankton impacted water quality and self-purification of lakes. Species and quantity of aquatic plants were the main factors to affect the change of pH and dissolved oxygen (DO), and loss of fertilizer and domestic wastewater were the main reasons for high nitrogen and phosphorus concentrations in lakes. Organic nitrogen was the main portion of TN by using excessive organic fertilizer in summer, NO 3 --N was the main portion in other seasons. The principal component analysis result showed that the three principal components of self-purification ability were phytoplankton factor (water temperature, pH, permanganate index and Chl-a), farm drainage factor (pH, DO and TN), nutrient factor (TN and TP). The cluster analysis result showed that the water quality of four seasons in 11 sampling sites of three lakes could be divided into two categories: first, in spring, autumn and winter; second, in summer. This was caused by the temperature changes and agricultural drainage. Water temperature and pH were used to calculate the concentrations of permanganate index, TN, TP, Chl-a by linear equations, which improved the quick prediction ability in locale.
Author keywords:
Cluster analysis; Linear fitting; Principal component analysis; Seasonal variation; Self-purification ability; Small shallow lake
Indexed keywords:
EMTREE drug terms: fresh water
EMTREE medical terms: article; bioremediation; China; environmental monitoring; principal component analysis; season; water management; water pollutant
MeSH: Biodegradation, Environmental; China; Environmental Monitoring; Fresh Water; Principal Component Analysis; Seasons; Water Pollutants, Chemical; Water Purification
Medline is the source for the MeSH terms of this document.
Chemicals and CAS Registry Numbers: Water Pollutants, Chemical
ISSN: 02503301 CODEN: HCKHDSource Type: Journal Original language: Chinese
PubMed ID: 20527172Document Type: Article
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© Copyright 2011 Elsevier B.V., All rights reserved. © MEDLINE® is the source for the MeSH terms of this document.
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2
Self-purification ability of a water-carrying lake
Ren, R.-L., Liu, M.-S., Zhang, J.-M., Zhang, M., Xu, M.
2007
Chinese Journal of Ecology 26 (8) , pp. 1222-1227.
Ren, R.-L.a , Liu, M.-S.a , Zhang, J.-M.b, Zhang, M.c, Xu, M.a
a School of Life Science, Nanjing University, Nanjing 210093, China
b Suqian Bureau of Forestry, Suqian 223800 Jiangsu, China
c Environmental Conservation Bureau of Suqian, Suqian 223800 Jiangsu, China
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Abstract
By using the 1991-2003 monitoring data of water quality at 5 sampling locations distributed nearby the 2 entrances and 3 exits of the luoma Lake river ways, the self-purification ability of the lake was studied. The results showed that on the whole, the water quality near the exits was better and more steady-going than that near the entrances, indicating that the lake still had strong self-purification ability. The coefficients of variation of the water quality indices among the 5 sampling locations decreased gradually, suggesting that the purification rates of total nitrogen, dissolved oxygen, volatile hydroxybenzene, non-ionic ammonia, and arsenic in water body reduced remarkably, and the self-purification ability of the lake was weakened. The coefficients of variation of total nitrogen and dissolved oxygen and some exogenous pollutants among various sampling locations could be used as the reference indices of self-purification ability and health status of wetland ecosystems.
Author keywords
Coefficients of variation; External contamination; Internal contamination; Luoma Lake; Water-carrying lake
Indexed keywords
GEOBASE Subject Index: arsenic; dissolved oxygen; lake water; monitoring; nitrogen; sampling; self purification; volatile organic compound; water pollution; water quality; wetland
Regional Index: Asia; China; Eurasia; Far East; Jiangsu; Luoma Lake
ISSN: 10004890 CODEN: SZAZESource Type: Journal Original language: Chinese
Document Type: Article
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Polyfunctional role of biodiversity in processes leading to water purification: Current conceptualizations and concluding remarks
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Ren, R.-L.; School of Life Science, Nanjing University, Nanjing 210093, China; email:renruili1004@163.com
© Copyright 2008 Elsevier B.V.
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Key words:
aquatic, ecosystem, bioreactor, water, self-purification, function, water quality, pollution, ecology, freshwater, marine, biodiversity
Key words:
aquatic, ecosystem, bioreactor, water, self-purification, function, water quality, pollution, ecology, freshwater, marine, biodiversity