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The role of nutrient loading and eutrophication in estuarine ecology.Casting your network wide: a plea to scale-up phenological researchNovel Approaches to Manipulating Bacterial Pathogen Biofilms: Whole-Systems Design Philosophy and Steering Microbial Evolution.Food-web models predict species abundances in response to habitat changeInteractions among predators and the cascading effects of vertebrate insectivores on arthropod communities and plantsFood web architecture and basal resources interact to determine biomass and stoichiometric cascades along a benthic food webComparing effects of lake- and watershed-scale influences on communities of aquatic invertebrates in shallow lakes.Increasing zooplankton size diversity enhances the strength of top-down control on phytoplankton through diet niche partitioning.Ecological and evolutionary effects of stickleback on community structureThe effect of temporal scale on the outcome of trophic cascade experiments.Strategies of zooplanktivory shape the dynamics and diversity of littoral plankton communities: a mesocosm approachGlobal ecological impacts of invasive species in aquatic ecosystems.High fishery catches through trophic cascades in China.Spider silk reduces insect herbivoryExperimental evidence for a behavior-mediated trophic cascade in a terrestrial food chain.Chytrid parasitism facilitates trophic transfer between bloom-forming cyanobacteria and zooplankton (Daphnia).Prey-driven control of predator assemblages: zooplankton abundance drives aquatic beetle colonization.Cross-habitat effects shape the ecosystem consequences of co-invasion by a pelagic and a benthic consumer.Early life-history predator-prey reversal in two cyprinid fishes.A highly unsaturated fatty acid predicts carbon transfer between primary producers and consumers.Consumer Versus Resource Control in Freshwater Pelagic Food WebsEvolutionary trade-offs in plants mediate the strength of trophic cascades.Induced defenses in herbivores and plants differentially modulate a trophic cascade.Asymmetry in community regulation: effects of predators and productivity.Predation on mutualists can reduce the strength of trophic cascades.Trophic cascades and trophic trickles in pelagic food webs.NUTRIENT LIMITATION REDUCES FOOD QUALITY FOR ZOOPLANKTON:DAPHNIARESPONSE TO SESTON PHOSPHORUS ENRICHMENTBiodiversity and ecosystem function: the consumer connectionWHAT DETERMINES THE STRENGTH OF A TROPHIC CASCADE?The strength of trophic cascades across ecosystems: predictions from allometry and energeticsNorth Atlantic Oscillation signatures in aquatic and terrestrial ecosystems-a meta-analysisEvidence against the use of surrogates for biomonitoring of Neotropical floodplainsCould increased cyanobacterial biomass following forest harvesting cause a reduction in zooplankton body size structure?Effects of experimentally induced cyanobacterial blooms on crustacean zooplankton communitiesThe structuring role of fish in Greenland lakes: an overview based on contemporary and paleoecological studies of 87 lakes from the low and the high ArcticInterspecific Differences in the Direct and Indirect Effects of Two Neotropical Hylid Tadpoles on Primary Producers and Zooplankton
P2860
Q24814645-CDF3A93F-6216-45AE-893F-2EEBEF97D91FQ28078639-A1BD7356-ED3C-4DD2-8142-870FA65D49BDQ30388216-8C381F69-A858-4A59-A1A9-0A39568E6A35Q33258481-9FE28331-A77A-41A4-96B7-0809345D526AQ33842174-CE3BAE4C-021D-4888-86B1-8AFB97A54A48Q33971358-A4CEF3CE-A7F3-4F7F-AF06-D0975031B3FBQ34412643-1515DDDC-38E2-4431-9058-2627DA3F636FQ34626395-44F339E1-A60B-41BA-9FA4-3B5E8E6E6053Q34661693-DC652B1B-135F-49EF-A064-7104339BC564Q35088817-20F3A1DB-4EC0-4E6B-8F45-FA42B568636EQ35667453-4E9F5157-152C-4F17-AE17-036FEC28A3C1Q35714903-5795FDAE-9000-46E8-83BA-16E5FE946FBDQ36234145-405D6CB3-C0DF-4E70-A54D-F79601C22847Q36590542-C4A64DDF-9FC2-4E38-9E15-A06942558ED9Q36593999-91FC9BA0-389D-4202-BD81-EC4C2195015CQ37335463-42224A4F-E131-498A-96F7-3DCAC6150CDEQ38749140-995D5524-9906-4DF5-9F55-80D34A657A6DQ39721888-2DCC1C29-925B-4344-968E-EF78D89081EEQ41191929-FB48D647-89C8-4AA4-AAC8-ABFBA30D95A3Q41714703-69DB3423-328B-4EDA-92C2-9F7A0356FD64Q45141131-055FE24A-06A0-434A-9F1E-9C615787D14DQ46924097-C982862C-B1F3-4C2A-BE61-81CEDD23155AQ51698979-D883010A-6E43-49C5-BC52-520E5BAB7910Q51716635-A859034C-7BB3-484B-ADC8-E589B9A8A4B4Q52673226-7FF22B64-9388-4CC3-9189-16510BE4FDB3Q55477053-350D9920-0161-4C69-B72E-C384734A144BQ56136796-AEFC336F-383E-44C5-AA71-2C7D8DF3CD3CQ56483771-AE53EB1E-E2CA-41D8-9F03-CEE555C53CFCQ56679391-7B9BC2CA-6EB0-4E9C-A9D7-DB30C0009F1CQ56930356-A04ADC29-4D8C-4FBE-80BF-DBFE6526CDEAQ57068815-FB857DB8-5E3E-46AA-A0BA-5619CBD28C58Q57191328-B84ACF14-7954-41DC-88E8-A48A58B0413EQ57239622-DF0E5519-616F-4BDE-B1E7-708ACAE8A3DFQ57239630-2B8015CF-E676-49A1-B941-447895C487BEQ57744259-7D5E4577-5DF5-46BC-8A98-799582F26728Q58288953-348DB203-CF33-4CD9-99B1-01E609484B12
P2860
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on July 1996
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
A meta-analysis of the freshwater trophic cascade.
@en
A meta-analysis of the freshwater trophic cascade.
@nl
type
label
A meta-analysis of the freshwater trophic cascade.
@en
A meta-analysis of the freshwater trophic cascade.
@nl
prefLabel
A meta-analysis of the freshwater trophic cascade.
@en
A meta-analysis of the freshwater trophic cascade.
@nl
P2860
P356
P1476
A meta-analysis of the freshwater trophic cascade.
@en
P2093
P2860
P304
P356
10.1073/PNAS.93.15.7723
P407
P577
1996-07-01T00:00:00Z