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Macrophytes

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Journal Article
Aquatic Ecosystem Health & Management (2014) 17 (2): 129–136.
Published: 03 April 2014
...A. O. Achieng’; P. O. Raburu; L. Okinyi; S. Wanjala King’wal wetland, at the upper catchment of Lake Victoria, is undergoing anthropogenic disturbances which degrade its health. In this study, the wetland's health was assessed using water quality parameters and wetland macrophytes, sampled monthly...
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Journal Article
Aquatic Ecosystem Health & Management (2006) 9 (1): 43–47.
Published: 01 January 2006
...J. H. Li; H. Y. Guo; J. L. Mu; X. R. Wang; D. Q. Yin Physiological and biochemical perturbations of some submerged macrophytes, including Ceratophyllum demersum, Vallisneria spiralis and Potamogeton maackianus, were investigated following 25-day exposures to different concentrations of dibutyl...
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Journal Article
Aquatic Ecosystem Health & Management (2017) 20 (4): 353–360.
Published: 02 October 2017
...) P. stratiotes was the only floating macrophyte in the lake. After release of the herbivores, plant species richness increased dramatically as six other species were collected regularly in the samples. No feeding damage from the herbivores released was ever recorded on any of them (Cabrera Walsh...
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Journal Article
Aquatic Ecosystem Health & Management (2009) 12 (4): 471–476.
Published: 30 November 2009
... aromatic hydrocarbons contaminated water, removal efficiencies of four submerged macrophytes to phenanthrene were investigated, following 40-day exposure to phenanthrene solutions in an outdoor-simulated experiment. During the exposure period, phenanthrene concentration in water, sediments and the roots...
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Published: 01 January 2006
Figure 1. Effect of DBP pollution on contents of MDA in submerged macrophytes. More
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Published: 01 January 2006
Figure 3. Effect of DBP pollution on contents of chlorophyll in submerged macrophytes. More
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Published: 01 January 2006
Figure 4. Effect of DBP pollution on contents of protein in submerged macrophytes. More
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Published: 01 January 2006
Figure 5. Effect of DBP pollution on contents of glutathione in submerged macrophytes. *Correlation is significant at the 0.05 level (2-tailed). More
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Published: 02 October 2014
Figure 2. Relationship between maximum depth of colonisation of macrophytes and the mean growing season of chlorophyll a . Lines mark regression model together with 5 th , 25 th , 75 th and 95 th percentiles of residuals. Vertical dotted arrow marks chlorophyll reference value More
Journal Article
Aquatic Ecosystem Health & Management (2016) 19 (4): 393–400.
Published: 01 October 2016
...Jian-Gang Zhao; Zhang-He Chen To evaluate the ecological restoration effect of floating and submerged macrophytes on phytoplankton inhibition and water quality improvement, an enclosure experiment was undertaken in situ including Hydrilla verticillata mono enclosure, Eichhornia crassipes mono...
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Journal Article
Aquatic Ecosystem Health & Management (2012) 15 (4): 385–396.
Published: 01 December 2012
...) index of fishes, estimated as the product of average seasonal biomass and P/B, was about 6x higher at the electrofishing transects with medium to high macrophyte cover and low fetch than at sites where macrophytes were absent or sparse and fetch was high. The production index -aquatic plant relationship...
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Published: 02 April 2016
Figure 6. Number of macrophyte species by functional group and WMI scores for (a) Hamilton Harbour, (b) Cootes Paradise and (c) Grindstone Marshes. More
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Published: 01 December 2012
Figure 3. Relationship between average macrophyte category at the study areas and average biomass (ln g transect −1 ), growth index (ω) and average fish size (weight in g) of Pumpkinseed (left) and Yellow Perch (right). More
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Published: 01 December 2012
Figure 4. Relationship between macrophyte cover and fish production indices. Production indices are shown for Pumpkinseed (dashed line, ▪), Yellow Perch (dotted line, X) and total fish (solid line, •). More
Journal Article
Aquatic Ecosystem Health & Management (2016) 19 (1): 49–57.
Published: 02 January 2016
...Tao Zhong; Yun-Hui Tian; Ben-Ru Song; Zong-Jing Chen; Yang Zhang; Zhang-He Chen We studied the removal of chlorophyll- a and eutrophic alga Ankistrodesmus acicularis by mixed and monoculture constructed wetlands of four common wetland macrophytes, Echinodorus berteroi, Hydrocotyle sibthorpioides...
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Journal Article
Aquatic Ecosystem Health & Management (2016) 19 (4): 368–381.
Published: 01 October 2016
..., accounting for the interplay among water column, sediments and macrophytes, to reproduce the observed total phosphorus dynamics over a 17-year period (1996–2012). Water level fluctuations were one of the key challenges for balancing the phosphorus budget during model calibration. Our analysis shows...
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Includes: Supplementary data
Journal Article
Aquatic Ecosystem Health & Management (2012) 15 (4): 442–452.
Published: 01 December 2012
... crossed the bay with sampling starting at 0.5 m water depth and ending 90 m beyond the last macrophyte. Seasonal survey timing varied from mid-July to mid-September with a sampling interval between one to six years. From 1972 to 1988, the survey protocol used a 30 m rope with knots placed at 1 m intervals...
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Journal Article
Aquatic Ecosystem Health & Management (2008) 11 (4): 465–473.
Published: 09 December 2008
... substrates are noted for OH reflecting the sluggish glide-pool channel morphology, but a more diverse range of vegetative habitats is observed at OH compared to NLF which is more shaded. The macrophytic communities and substrate composition at OH ( Figure 1 ) are characteristic of a slower-flowing...
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Journal Article
Aquatic Ecosystem Health & Management (2014) 17 (4): 424–436.
Published: 02 October 2014
...Figure 2. Relationship between maximum depth of colonisation of macrophytes and the mean growing season of chlorophyll a . Lines mark regression model together with 5 th , 25 th , 75 th and 95 th percentiles of residuals. Vertical dotted arrow marks chlorophyll reference value...
FIGURES
Journal Article
Aquatic Ecosystem Health & Management (2015) 18 (4): 467–474.
Published: 02 October 2015
... and/or reducing macrophyte coverage that would give space and nutrients for phytoplankton growth. Table 1. Salient features of the Akaipur and Bhomra wetlands (with mean values of some of the parameters ± standard error). Akaipur Wetland Bhomra Wetland Area (ha) 32 83 Depth (m) 0.3–1.8...
FIGURES
Includes: Supplementary data