Goldman revisited: Faster-growing phytoplankton has lower N : P and lower stoichiometric flexibility
about
A new approach to homeostatic regulation: towards a unified view of physiological and ecological conceptsStoichiometric flexibility in diverse aquatic heterotrophic bacteria is coupled to differences in cellular phosphorus quotas.Interaction Effects of Light, Temperature and Nutrient Limitations (N, P and Si) on Growth, Stoichiometry and Photosynthetic Parameters of the Cold-Water Diatom Chaetoceros wighamii.Toward an ecologically meaningful view of resource stoichiometry in DOM-dominated aquatic systemsStoichiometric regulation of phytoplankton toxins.Unifying ecological stoichiometry and metabolic theory to predict production and trophic transfer in a marine planktonic food web.Aquatic heterotrophic bacteria have highly flexible phosphorus content and biomass stoichiometry.Toward an Ecologically Optimized N:P Recovery from Wastewater by Microalgae.Non-Redfield, nutrient synergy and flexible internal elemental stoichiometry in a marine bacterium.Determining Inorganic and Organic Phosphorus.The impact of irradiance on optimal and cellular nitrogen to phosphorus ratios in phytoplankton.Multiple vs. single phytoplankton species alter stoichiometry of trophic interaction with zooplankton.Growth rate and resource imbalance interactively control biomass stoichiometry and elemental quotas of aquatic bacteria.Warming advances top-down control and reduces producer biomass in a freshwater plankton communityImpacts of Nitrogen and Phosphorus: From Genomes to Natural Ecosystems and AgricultureMechanisms of P* Reduction in the Eastern Tropical South PacificNon-Redfieldian Dynamics Explain Seasonal pCO2 Drawdown in the Gulf of Bothnia
P2860
Q28543165-0901898C-C5EF-4C9A-BA18-34D2ABCDE794Q35128516-0AFFD95D-9E7D-43CC-9031-363AF7482877Q35636777-9BEC8E85-08AD-4CE5-90FB-61B0458FD658Q35891518-12246AC7-E69F-4D90-B1F8-321D929AA5E3Q38202997-B822F2F7-929E-4C25-8D3A-9B7C0500B38BQ40585622-81C14BCD-2862-47E4-B10F-F1A680BFA739Q41179357-9AD70A59-7553-4BF3-B5A7-6CAB2E1E5C91Q41684263-FA587E71-A9A7-4980-A025-A3E654404184Q42223527-3904DF5C-B4E6-401C-BDD1-AE9627C62801Q46257372-D4F6045C-7128-4F0A-9554-0AA035642071Q46539124-F4CF7F60-8232-429D-AF42-FE791DB9BFFCQ46564928-1A580337-358E-494B-B7A3-C95E5CFA3008Q48016018-74D157EA-AF71-4635-8557-9D10EC6474D9Q57022198-CFF2FF9E-91E3-4C78-B352-64675ACF33E2Q57262387-CECF7490-3946-4611-99F6-2635954EBC38Q57901036-71176505-C322-46DB-B0C0-26918FE6F8FBQ58402859-4EEAD7E4-E7E5-4591-B2C6-C6E21CD0EC78
P2860
Goldman revisited: Faster-growing phytoplankton has lower N : P and lower stoichiometric flexibility
description
2013 nî lūn-bûn
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2013年の論文
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2013年学术文章
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2013年学术文章
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2013年学术文章
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Goldman revisited: Faster-grow ...... wer stoichiometric flexibility
@en
Goldman revisited: Faster-grow ...... wer stoichiometric flexibility
@nl
type
label
Goldman revisited: Faster-grow ...... wer stoichiometric flexibility
@en
Goldman revisited: Faster-grow ...... wer stoichiometric flexibility
@nl
prefLabel
Goldman revisited: Faster-grow ...... wer stoichiometric flexibility
@en
Goldman revisited: Faster-grow ...... wer stoichiometric flexibility
@nl
P50
P1476
Goldman revisited: Faster-grow ...... wer stoichiometric flexibility
@en
P2093
Arne Malzahn
Christoph Plum
P304
P356
10.4319/LO.2013.58.6.2076
P577
2013-10-21T00:00:00Z