Rationale for control of anthropogenic nitrogen and phosphorus to reduce eutrophication of inland waters.
about
Environmentally induced, occupational diseases with emphasis on chronic kidney disease of multifactorial origin affecting tropical countriesPhytoplankton-specific response to enrichment of phosphorus-rich surface waters with ammonium, nitrate, and ureaPartitioning the Relative Importance of Phylogeny and Environmental Conditions on Phytoplankton Fatty AcidsMitigating harmful cyanobacterial blooms in a human- and climatically-impacted worldSeasonal patterns of nitrogen and phosphorus limitation in four German lakes and the predictability of limitation status from ambient nutrient concentrationsNitrogen limitation of pond ecosystems on the plains of Eastern ColoradoControlling cyanobacterial blooms in hypertrophic Lake Taihu, China: will nitrogen reductions cause replacement of non-N2 fixing by N2 fixing taxa?Toxic cyanobacterial bloom triggers in missisquoi bay, lake champlain, as determined by next-generation sequencing and quantitative PCRBiogeochemistry of beetle-killed forests: explaining a weak nitrate response.In-situ Adsorption-Biological Combined Technology Treating Sediment Phosphorus in all Fractions.Microcystin Biosynthesis and mcyA Expression in Geographically Distinct Microcystis Strains under Different Nitrogen, Phosphorus, and Boron Regimes.Nitrogen forms influence microcystin concentration and composition via changes in cyanobacterial community structure.Duelling 'CyanoHABs': unravelling the environmental drivers controlling dominance and succession among diazotrophic and non-N2 -fixing harmful cyanobacteria.The cyanobacterial nitrogen fixation paradox in natural waters.The impact of water pollution on fish species in southeast region of Goiás, Brazil.Critical nutrient thresholds needed to control eutrophication and synergistic interactions between phosphorus and different nitrogen sources.Biological and chemical factors driving the temporal distribution of cyanobacteria and heterotrophic bacteria in a eutrophic lake (West Lake, China).Controlling cyanobacterial harmful blooms in freshwater ecosystems.Screening the toxicity of phosphorous-removal adsorbents using a bioluminescence inhibition test.Effects of supersaturation control strategies on hydroxyapatite (HAP) crystallization for phosphorus recovery from wastewater.Isolation and characterization of dissolved organic matter fractions from antialgal products of Microcystis aeruginosa.Spatial and temporal variability in the nitrogen cyclers of hypereutrophic Lake Taihu.Determining ecoregional numeric nutrient criteria by stressor-response models in Yungui ecoregion lakes, China.Mercury and other trace elements in Ohio River fish collected near coal-fired power plants: Interspecific patterns and consideration of consumption risks.Mitigating Toxic Planktonic Cyanobacterial Blooms in Aquatic Ecosystems Facing Increasing Anthropogenic and Climatic Pressures.The Impact of Warming and Nutrients on Algae Production and Microcystins in Seston from the Iconic Lake Lesser Prespa, Greece.The dilemma of controlling cultural eutrophication of lakes.Species richness-phosphorus relationships for lakes and streams worldwideThe metabolic regimes of flowing watersNitrogen cycling in a freshwater estuaryInvestigation on the adsorption of phosphorus in all fractions from sediment by modified maifaniteNew insights on resource stoichiometry: assessing availability of carbon, nitrogen, and phosphorus to bacterioplanktonMitigating harmful cyanobacterial blooms: strategies for control of nitrogen and phosphorus loadsSpatial variability in sediment phosphorus characteristics along a hydrological gradient upstream of Lake Rotorua, New ZealandBioavailability of phosphorus transported during storm flow to a eutrophic, polymictic lakeQuantifying temporal and spatial variations in sediment, nitrogen and phosphorus transport in stream inflows to a large eutrophic lakeStormwater runoff driven phosphorus transport in an urban residential catchment: Implications for protecting water quality in urban watersheds
P2860
Q26738623-892F446A-763B-4D9E-BFD4-B17EB30EE5F7Q28485178-684353F9-A996-4D91-BACE-FB5443B0537AQ28548357-5A5050AC-6902-4F1E-B929-0BEA37E90D22Q28652683-2FBBCA07-4335-4A95-8B02-F0E3A82E25BDQ35155216-EA1A7E02-0D45-4495-8650-30BE72DF64EAQ35168100-CD862BCF-F41D-4458-BE02-92B1CC5788B7Q35431791-594EDCAC-5001-4345-88F4-F9067427ABA1Q35845520-CE403321-F3D7-40A1-BDEF-B1271DC19757Q36583031-4247E2AB-481B-44AA-89D4-319285269BE5Q37096688-1CDD982B-3916-4BCB-8609-ABD49D6D32AFQ37359694-B04A419D-F0AA-414D-8FB9-0ABFA1559863Q37464783-2A7F28BF-4808-4505-A015-925B1F375604Q38574517-B3E0A720-1161-4D6E-B112-37B342D4E831Q38868113-2F2774C0-9147-4FC2-83FF-26C04AA00846Q40176050-B61088D9-5087-4E03-B6E1-348A531E4E22Q40395134-61C18B6F-A775-4384-B4FB-8FBB8CCA36DBQ40474130-97DB25CE-C410-4C41-871E-6E77EC0AD0F4Q41693471-F1A21978-4B77-499E-B133-469366483AA6Q43324831-9496B209-3A96-4A95-AD9A-590B90845D75Q43358313-B2C0003B-3564-4BDC-95D8-C052C3A5696CQ46036035-97C6A6CC-1CB1-405D-8F90-0C289AB4E8D8Q46398649-050D924E-1811-4C93-A583-26F0906F31A1Q46617973-5A77D6BD-B95A-43E1-888D-8B512C64A05EQ46786896-E4016F6A-AA38-4747-85DC-D70D13B29C7CQ50117516-D8C11C16-9F0F-4201-96B3-FAB778E4C335Q55391594-E731E8A4-BD0F-43A7-81FB-49E11C80FBCDQ55554391-FB1BDA8E-9BD0-45D5-A7B8-254F70E2A7A3Q56932358-55BE0CBE-D63B-4782-9D63-E310459C4A80Q57052503-1303AB82-B5AD-440A-9104-403406084176Q57272838-D6F46F41-C6C3-4278-8348-56216336C448Q57799769-5B5C599C-7AB8-4347-AC88-E513EC518C9AQ57890350-1898A5A4-983F-4152-A636-482DAEEA8C99Q58067011-E303188F-8775-40B4-83D9-81130072EB8EQ58067111-04BCE448-2FE4-4C0E-A825-54A7D2813C7CQ58067114-33D9B0DA-431E-441B-8AEA-418145654B04Q58067132-8E53C09B-3AE4-45B8-8DF1-71806CF7FDE3Q58802362-A0DBA60E-F92C-4D44-8E1E-BCAB0F4CCFB0
P2860
Rationale for control of anthropogenic nitrogen and phosphorus to reduce eutrophication of inland waters.
description
2011 nî lūn-bûn
@nan
2011年の論文
@ja
2011年学术文章
@wuu
2011年学术文章
@zh
2011年学术文章
@zh-cn
2011年学术文章
@zh-hans
2011年学术文章
@zh-my
2011年学术文章
@zh-sg
2011年學術文章
@yue
2011年學術文章
@zh-hant
name
Rationale for control of anthr ...... trophication of inland waters.
@en
Rationale for control of anthr ...... trophication of inland waters.
@nl
type
label
Rationale for control of anthr ...... trophication of inland waters.
@en
Rationale for control of anthr ...... trophication of inland waters.
@nl
prefLabel
Rationale for control of anthr ...... trophication of inland waters.
@en
Rationale for control of anthr ...... trophication of inland waters.
@nl
P2093
P356
P1476
Rationale for control of anthr ...... trophication of inland waters.
@en
P2093
Hans W Paerl
Wayne A Wurtsbaugh
William M Lewis
P304
10300-10305
P356
10.1021/ES202401P
P407
P577
2011-11-23T00:00:00Z