Global Biogeochemical Cycles, ISSN 0886-6236, 03/2018, Volume 32, Issue 3, pp. 486 - 496
Phosphorus is believed to be the globally limiting nutrient in the modern ocean, but a number of nutrients have been invoked as limiting the Proterozoic...
nutrient limitation | Proterozoic | oxygenation | primary productivity | RATIOS | ATMOSPHERIC OXYGEN | PHOSPHORUS | OCEAN | CARBON-CYCLE | IRON | ENVIRONMENTAL SCIENCES | GEOSCIENCES, MULTIDISCIPLINARY | NITROGEN | CONSEQUENCES | DEGRADATION | METEOROLOGY & ATMOSPHERIC SCIENCES | ORGANIC-MATTER PRESERVATION | Nutrients (mineral) | Oxygen | Anoxia | Phosphorus | Iron | Net Primary Productivity | Molybdenum | Precambrian | Constraining | Environments | Biosphere | Evolution | Nutrients | Primary production
nutrient limitation | Proterozoic | oxygenation | primary productivity | RATIOS | ATMOSPHERIC OXYGEN | PHOSPHORUS | OCEAN | CARBON-CYCLE | IRON | ENVIRONMENTAL SCIENCES | GEOSCIENCES, MULTIDISCIPLINARY | NITROGEN | CONSEQUENCES | DEGRADATION | METEOROLOGY & ATMOSPHERIC SCIENCES | ORGANIC-MATTER PRESERVATION | Nutrients (mineral) | Oxygen | Anoxia | Phosphorus | Iron | Net Primary Productivity | Molybdenum | Precambrian | Constraining | Environments | Biosphere | Evolution | Nutrients | Primary production
Journal Article
Ecological Applications, ISSN 1051-0761, 1/2010, Volume 20, Issue 1, pp. 5 - 15
Nutrient limitation to primary productivity and other biological processes is widespread in terrestrial ecosystems, and nitrogen (N) and phosphorus (P) are the...
Pedogenesis | Invited Feature: Perspectives on the Modern Nitrogen Cycle | Terrestrial ecosystems | Soil parent materials | Ecosystems | Marine ecosystems | Forest ecosystems | Nitrogen | Soil ecology | Forest soils | Soil resources | nutrient limitation | chronosequence | biogeochemistry | nitrogen | proximate vs. ultimate | phosphorus | Proximate vs. Ultimate | Phosphorus | Biogeochemistry | Chronosequence | Nutrient limitation | ECOSYSTEM DEVELOPMENT | DINITROGEN FIXATION | TROPICAL FOREST | EUTROPHICATION | ENVIRONMENTAL SCIENCES | SOIL-PHOSPHORUS | AVAILABILITY | GROWTH | HAWAIIAN MONTANE FOREST | ECOLOGY | BIOGEOCHEMICAL THEORY | Nitrogen - metabolism | Climate Change | Nitrogen - chemistry | Phosphorus - metabolism | Ecosystem | Phosphorus - chemistry | Nitrogen Fixation
Pedogenesis | Invited Feature: Perspectives on the Modern Nitrogen Cycle | Terrestrial ecosystems | Soil parent materials | Ecosystems | Marine ecosystems | Forest ecosystems | Nitrogen | Soil ecology | Forest soils | Soil resources | nutrient limitation | chronosequence | biogeochemistry | nitrogen | proximate vs. ultimate | phosphorus | Proximate vs. Ultimate | Phosphorus | Biogeochemistry | Chronosequence | Nutrient limitation | ECOSYSTEM DEVELOPMENT | DINITROGEN FIXATION | TROPICAL FOREST | EUTROPHICATION | ENVIRONMENTAL SCIENCES | SOIL-PHOSPHORUS | AVAILABILITY | GROWTH | HAWAIIAN MONTANE FOREST | ECOLOGY | BIOGEOCHEMICAL THEORY | Nitrogen - metabolism | Climate Change | Nitrogen - chemistry | Phosphorus - metabolism | Ecosystem | Phosphorus - chemistry | Nitrogen Fixation
Journal Article
Ecology Letters, ISSN 1461-023X, 09/2011, Volume 14, Issue 9, pp. 852 - 862
Ecology Letters (2011) 14: 852–862 Synergistic interactions between multiple limiting resources are common, highlighting the importance of co‐limitation as a...
stoichiometry | Autotroph | von Liebig | nitrogen | plant biomass | plant community | meta‐analysis | multiple nutrient limitation | co‐limitation | phosphorus | Stoichiometry | Co-limitation | Plant community | Plant biomass | Phosphorus | Von Liebig | Nitrogen | Multiple nutrient limitation | Meta-analysis | ATMOSPHERIC NITROGEN DEPOSITION | PHOSPHORUS LIMITATION | meta-analysis | FRESH-WATER | COLIMITATION | ENRICHMENT | ECOLOGY | PRIMARY PRODUCTIVITY | DIVERSITY | co-limitation | MARINE | PHYTOPLANKTON | Phosphorus - analysis | Nitrogen - metabolism | Plants - metabolism | Nitrogen - analysis | Phosphorus - metabolism | Ecosystem | Soil - chemistry | Fresh Water - chemistry | Seawater - chemistry | Biomass | Behavior evolution | Analysis | Nutrients | Ecology
stoichiometry | Autotroph | von Liebig | nitrogen | plant biomass | plant community | meta‐analysis | multiple nutrient limitation | co‐limitation | phosphorus | Stoichiometry | Co-limitation | Plant community | Plant biomass | Phosphorus | Von Liebig | Nitrogen | Multiple nutrient limitation | Meta-analysis | ATMOSPHERIC NITROGEN DEPOSITION | PHOSPHORUS LIMITATION | meta-analysis | FRESH-WATER | COLIMITATION | ENRICHMENT | ECOLOGY | PRIMARY PRODUCTIVITY | DIVERSITY | co-limitation | MARINE | PHYTOPLANKTON | Phosphorus - analysis | Nitrogen - metabolism | Plants - metabolism | Nitrogen - analysis | Phosphorus - metabolism | Ecosystem | Soil - chemistry | Fresh Water - chemistry | Seawater - chemistry | Biomass | Behavior evolution | Analysis | Nutrients | Ecology
Journal Article
Oikos, ISSN 0030-1299, 02/2015, Volume 124, Issue 2, pp. 113 - 121
Humans are modifying the availability of nutrients such as nitrogen (N) and phosphorus (P), and it is therefore important to understand how these nutrients,...
MINERAL-NUTRITION | PACIFIC-OCEAN | RESOURCE LIMITATION | AVAILABILITY | FUNCTIONAL TYPES | ECOLOGY | COMMUNITIES | PLANT-GROWTH | INTERTIDAL MACROALGA | FRESH-WATER | SUBTROPICAL NORTH | Nutrients | Phosphorus | Nitrogen | Ecosystems
MINERAL-NUTRITION | PACIFIC-OCEAN | RESOURCE LIMITATION | AVAILABILITY | FUNCTIONAL TYPES | ECOLOGY | COMMUNITIES | PLANT-GROWTH | INTERTIDAL MACROALGA | FRESH-WATER | SUBTROPICAL NORTH | Nutrients | Phosphorus | Nitrogen | Ecosystems
Journal Article
Ecology, ISSN 0012-9658, 8/2007, Volume 88, Issue 8, pp. 2105 - 2113
With anthropogenic nutrient inputs to ecosystems increasing globally, there are long-standing, fundamental questions about the role of nutrients in the...
Mining | Soil microorganisms | Ecosystems | Soil organic matter | Soil nutrients | Biomass | Nitrogen | Soil respiration | Organic soils | Soil ecology | fertilization | microbial nitrogen mining | stoichiometric theory | carbon sequestration | South Africa | decomposition | Kruger National Park | Kruger National Park, South Africa | Microbial nitrogen mining | Decomposition | Stoichiometric theory | Fertilization | Carbon sequestration | LITTER DECOMPOSITION | CARBON | FOREST ECOSYSTEMS | DEPOSITION | IMMOBILIZATION | MINERALIZATION | DYNAMICS | ECOLOGY | ADDITIONS | SOIL ORGANIC-MATTER | CLIMATE | Carbon - metabolism | Nitrogen - metabolism | Species Specificity | Stochastic Processes | Soil Microbiology | Ecosystem | Soil - analysis | Plant Physiological Phenomena | Biodiversity | Fertilizers | Biodegradation | Environmental aspects | Evaluation | Fixation | Chemical properties
Mining | Soil microorganisms | Ecosystems | Soil organic matter | Soil nutrients | Biomass | Nitrogen | Soil respiration | Organic soils | Soil ecology | fertilization | microbial nitrogen mining | stoichiometric theory | carbon sequestration | South Africa | decomposition | Kruger National Park | Kruger National Park, South Africa | Microbial nitrogen mining | Decomposition | Stoichiometric theory | Fertilization | Carbon sequestration | LITTER DECOMPOSITION | CARBON | FOREST ECOSYSTEMS | DEPOSITION | IMMOBILIZATION | MINERALIZATION | DYNAMICS | ECOLOGY | ADDITIONS | SOIL ORGANIC-MATTER | CLIMATE | Carbon - metabolism | Nitrogen - metabolism | Species Specificity | Stochastic Processes | Soil Microbiology | Ecosystem | Soil - analysis | Plant Physiological Phenomena | Biodiversity | Fertilizers | Biodegradation | Environmental aspects | Evaluation | Fixation | Chemical properties
Journal Article
New Phytologist, ISSN 0028-646X, 6/2012, Volume 194, Issue 4, pp. 953 - 960
Growth of plants in terrestrial ecosystems is often limited by the availability of nitrogen (N) or phosphorous (P) Liebig's law of the minimum states that the...
Full papers | Terrestrial ecosystems | Plant growth | Plant nutrition | Nutrient nutrient interactions | Nutrient availability | Phosphorus | Marine ecosystems | Plants | Nutrient uptake | Nitrogen | plant growth | Liebig’s law | carbon | nitrogen | model | multiple limitation hypothesis (MLH) | co‐limitation | phosphorus | Liebig's law | Co-limitation | Model | Multiple limitation hypothesis (MLH) | Carbon | ROOT | SEEDLINGS | STOICHIOMETRY | SHOOT RATIOS | PLANT SCIENCES | co-limitation | THOUGHTS | Nitrogen - metabolism | Plants - metabolism | Plant Development | Models, Biological | Phosphorus - metabolism | Miljö- och naturvårdsvetenskap | Environmental Sciences related to Agriculture and Land-use
Full papers | Terrestrial ecosystems | Plant growth | Plant nutrition | Nutrient nutrient interactions | Nutrient availability | Phosphorus | Marine ecosystems | Plants | Nutrient uptake | Nitrogen | plant growth | Liebig’s law | carbon | nitrogen | model | multiple limitation hypothesis (MLH) | co‐limitation | phosphorus | Liebig's law | Co-limitation | Model | Multiple limitation hypothesis (MLH) | Carbon | ROOT | SEEDLINGS | STOICHIOMETRY | SHOOT RATIOS | PLANT SCIENCES | co-limitation | THOUGHTS | Nitrogen - metabolism | Plants - metabolism | Plant Development | Models, Biological | Phosphorus - metabolism | Miljö- och naturvårdsvetenskap | Environmental Sciences related to Agriculture and Land-use
Journal Article
Ecology Letters, ISSN 1461-023X, 02/2012, Volume 15, Issue 2, pp. 142 - 150
There is growing consensus that the growth of herbivorous consumers is frequently limited by more than one nutrient simultaneously. This understanding,...
Multi-nutrient limitation | Essential resources | Food quality | Von Liebig | Eicosapentaenoic acid | Cholesterol | Daphnia magna | Herbivore | Nutritional ecology | food quality | STOICHIOMETRY | STEROLS | nutritional ecology | herbivore | FRESH-WATER | eicosapentaenoic acid | essential resources | PRIMARY PRODUCERS | von Liebig | EXCESS CARBON | multi-nutrient limitation | DAPHNIA-MAGNA | LIMITING NUTRIENTS | POLYUNSATURATED FATTY-ACIDS | ECOLOGY | NUTRITIONAL CONSTRAINTS | Models, Theoretical | Daphnia - growth & development | Animals | Animal Nutritional Physiological Phenomena | Herbivory - physiology | Models, Biological | Ecosystem | Eicosapentaenoic Acid - metabolism | Cholesterol - metabolism | Unsaturated fatty acids | Analysis | Omega-3 fatty acids
Multi-nutrient limitation | Essential resources | Food quality | Von Liebig | Eicosapentaenoic acid | Cholesterol | Daphnia magna | Herbivore | Nutritional ecology | food quality | STOICHIOMETRY | STEROLS | nutritional ecology | herbivore | FRESH-WATER | eicosapentaenoic acid | essential resources | PRIMARY PRODUCERS | von Liebig | EXCESS CARBON | multi-nutrient limitation | DAPHNIA-MAGNA | LIMITING NUTRIENTS | POLYUNSATURATED FATTY-ACIDS | ECOLOGY | NUTRITIONAL CONSTRAINTS | Models, Theoretical | Daphnia - growth & development | Animals | Animal Nutritional Physiological Phenomena | Herbivory - physiology | Models, Biological | Ecosystem | Eicosapentaenoic Acid - metabolism | Cholesterol - metabolism | Unsaturated fatty acids | Analysis | Omega-3 fatty acids
Journal Article
BMC Evolutionary Biology, ISSN 1471-2148, 05/2018, Volume 18, Issue 1, pp. 72 - 15
Adaptive responses to nutrient limitation involve mutations that increase the efficiency of usage or uptake of the limiting nutrient. However, starvation of...
Low nutrient environment | Experimental evolution | Nitrogen limitation | Magnesium limitation | Genes, Bacterial | Genome, Bacterial | Escherichia coli - drug effects | Adaptation, Physiological - drug effects | Ions | Magnesium - pharmacology | Sequence Analysis, DNA | Biological Evolution | Genetic Fitness | Escherichia coli - genetics | Base Sequence | Alleles | DNA Transposable Elements - genetics | Lipopolysaccharides - pharmacology | Escherichia coli Proteins - genetics | Hydrophobic and Hydrophilic Interactions | Nitrogen - pharmacology | Bacterial Toxins - genetics | Escherichia coli - physiology | Loss of Function Mutation - genetics | Metals - pharmacology | Escherichia coli | Physiological aspects | Genetic aspects | Research | Magnesium | Genetic transcription | Nitrogen | Biological Sciences | Naturvetenskap | Biologiska vetenskaper | Evolutionsbiologi | Natural Sciences | Evolutionary Biology
Low nutrient environment | Experimental evolution | Nitrogen limitation | Magnesium limitation | Genes, Bacterial | Genome, Bacterial | Escherichia coli - drug effects | Adaptation, Physiological - drug effects | Ions | Magnesium - pharmacology | Sequence Analysis, DNA | Biological Evolution | Genetic Fitness | Escherichia coli - genetics | Base Sequence | Alleles | DNA Transposable Elements - genetics | Lipopolysaccharides - pharmacology | Escherichia coli Proteins - genetics | Hydrophobic and Hydrophilic Interactions | Nitrogen - pharmacology | Bacterial Toxins - genetics | Escherichia coli - physiology | Loss of Function Mutation - genetics | Metals - pharmacology | Escherichia coli | Physiological aspects | Genetic aspects | Research | Magnesium | Genetic transcription | Nitrogen | Biological Sciences | Naturvetenskap | Biologiska vetenskaper | Evolutionsbiologi | Natural Sciences | Evolutionary Biology
Journal Article
Global Change Biology, ISSN 1354-1013, 02/2016, Volume 22, Issue 2, pp. 934 - 943
Nitrogen (N) and phosphorus (P), either individually or in combination, have been demonstrated to limit biomass production in terrestrial ecosystems. Field...
terrestrial ecosystem | global synthesis | belowground biomass production | plant N concentration | aboveground biomass production | plant P concentration | P limitation | Global synthesis | Terrestrial ecosystem | Plant N concentration | Aboveground biomass production | Belowground biomass production | Plant P concentration | N-P RATIOS | FERTILIZATION | DINITROGEN FIXATION | DEPOSITION | TERRESTRIAL ECOSYSTEMS | GLOBAL ANALYSIS | NUTRIENT LIMITATION | FOREST | ENVIRONMENTAL SCIENCES | SOIL-NITROGEN | PLANTS | ECOLOGY | BIODIVERSITY CONSERVATION | Phosphorus - pharmacology | Ecosystem | Soil - chemistry | Nitrogen - pharmacology | Plant Development - drug effects | Biomass | Fertilizers | Analysis | Phosphorus | Terrestrial ecosystems | Nitrogen | Meta-analysis
terrestrial ecosystem | global synthesis | belowground biomass production | plant N concentration | aboveground biomass production | plant P concentration | P limitation | Global synthesis | Terrestrial ecosystem | Plant N concentration | Aboveground biomass production | Belowground biomass production | Plant P concentration | N-P RATIOS | FERTILIZATION | DINITROGEN FIXATION | DEPOSITION | TERRESTRIAL ECOSYSTEMS | GLOBAL ANALYSIS | NUTRIENT LIMITATION | FOREST | ENVIRONMENTAL SCIENCES | SOIL-NITROGEN | PLANTS | ECOLOGY | BIODIVERSITY CONSERVATION | Phosphorus - pharmacology | Ecosystem | Soil - chemistry | Nitrogen - pharmacology | Plant Development - drug effects | Biomass | Fertilizers | Analysis | Phosphorus | Terrestrial ecosystems | Nitrogen | Meta-analysis
Journal Article
Science, ISSN 0036-8075, 11/2009, Volume 326, Issue 5954, pp. 835 - 837
Human activities have more than doubled the amount of nitrogen (N) circulating in the biosphere. One major pathway of this anthropogenic N input into...
Stoichiometry | Limnology | Geographic regions | Marine ecology | Watersheds | Lakes | Phytoplankton | Nutrients | Reports | Freshwater ecology | Atmospherics | MULTIDISCIPLINARY SCIENCES | PHOSPHORUS LIMITATION | ENRICHMENT | DIVERSITY | DAPHNIA | COMMUNITIES | ECOSYSTEMS | PHYTOPLANKTON | EUTROPHICATION | CYCLE | Trees | Phosphorus - analysis | Nitrogen - analysis | Humans | Fresh Water - chemistry | Biomass | Biodiversity | Food Chain | Sweden | Phytoplankton - growth & development | Norway | Colorado | Ecosystem | Atmosphere - chemistry | Human Activities | Phytoplankton - physiology | Nitrates - analysis | Nitrogen in the body | Research | Lake ecology | Methods | Distribution | Phosphorus | Nitrogen | Atmospheric sciences | Human influences | Human | Ecology | Deposition | Biological diversity
Stoichiometry | Limnology | Geographic regions | Marine ecology | Watersheds | Lakes | Phytoplankton | Nutrients | Reports | Freshwater ecology | Atmospherics | MULTIDISCIPLINARY SCIENCES | PHOSPHORUS LIMITATION | ENRICHMENT | DIVERSITY | DAPHNIA | COMMUNITIES | ECOSYSTEMS | PHYTOPLANKTON | EUTROPHICATION | CYCLE | Trees | Phosphorus - analysis | Nitrogen - analysis | Humans | Fresh Water - chemistry | Biomass | Biodiversity | Food Chain | Sweden | Phytoplankton - growth & development | Norway | Colorado | Ecosystem | Atmosphere - chemistry | Human Activities | Phytoplankton - physiology | Nitrates - analysis | Nitrogen in the body | Research | Lake ecology | Methods | Distribution | Phosphorus | Nitrogen | Atmospheric sciences | Human influences | Human | Ecology | Deposition | Biological diversity
Journal Article