Should phosphorus availability be constraining moist tropical forest responses to increasing CO2 concentrations
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[1] G. Farquhar,et al. Do slow‐growing species and nutrient‐stressed plants consistently respond less to elevated CO2? A clarification of some issues raised by Poorter 1998 ) , 2000 .
[2] J. Grace,et al. Interaction of nutrient limitation and elevated CO2 concentration on carbon assimilation of a tropical tree seedling (Cedrela odorata). , 2000, Tree physiology.
[3] P. Vitousek,et al. Regulation of soil phosphatase and chitinase activityby N and P availability , 2000 .
[4] J. Boone Kauffman,et al. BIOMASS, CARBON, AND NUTRIENT DYNAMICS OF SECONDARY FORESTS IN A HUMID TROPICAL REGION OF MÉXICO , 1999 .
[5] M. Watt,et al. Linking development and determinacy with organic acid efflux from proteoid roots of white lupin grown with low phosphorus and ambient or elevated atmospheric CO2 concentration , 1999, Plant physiology.
[6] D. Baldocchi,et al. The carbon balance of tropical, temperate and boreal forests , 1999 .
[7] J. Lloyd,et al. Current perspectives on the terrestrial carbon cycle , 1999 .
[8] Ian G. Enting,et al. Reconstructing the recent carbon cycle from atmospheric CO2, δ13C and O2/N2 observations* , 1999 .
[9] C. Lovelock,et al. Growth responses of seedlings of early and late successional tropical forest trees to elevated atmospheric CO2 , 1999 .
[10] A. Lugo,et al. Soil oxygen availability and biogeochemistry along rainfall and topographic gradients in upland wet tropical forest soils , 1999 .
[11] B. Holben,et al. Long‐term monitoring of atmospheric aerosols in the Amazon Basin: Source identification and apportionment , 1998 .
[12] J. Martins,et al. Large-scale aerosol source apportionment in Amazonia , 1998 .
[13] Yadvinder Malhi,et al. Carbon dioxide transfer over a Central Amazonian rain forest , 1998 .
[14] C. Körner,et al. In situ responses to elevated CO2 in tropical forest understorey plants , 1998 .
[15] A. Fitter,et al. Does elevated atmospheric carbon dioxide affect arbuscular mycorrhizas? , 1998, Trends in ecology & evolution.
[16] Peter M. Vitousek,et al. Changing sources of base cations during ecosystem development , 1998 .
[17] Phillips,et al. Changes in the carbon balance of tropical forests: evidence from long-term plots , 1998, Science.
[18] H. Poorter. Do slow‐growing species and nutrient‐stressed plants respond relatively strongly to elevated CO2? , 1998 .
[19] W. McDowell. Internal nutrient fluxes in a Puerto Rican rain forest , 1998, Journal of Tropical Ecology.
[20] L. Bruijnzeel,et al. Spatial heterogeneity of element and litter turnover in a Bornean rain forest , 1998, Journal of Tropical Ecology.
[21] J. Bhatti,et al. Influence of oxalate and soil organic matter on sorption and desorption of phosphate onto a spodic horizon , 1998 .
[22] D. Barrett,et al. Elevated atmospheric CO2 concentrations increase wheat root phosphatase activity when growth is limited by phosphorus , 1998 .
[23] D. Schachtman,et al. Phosphorus Uptake by Plants: From Soil to Cell , 1998, Plant physiology.
[24] D. A. King,et al. Modelling forest‐growth response to increasing CO2 concentration in relation to various factors affecting nutrient supply , 1998 .
[25] I. Alexander,et al. PHOSPHORUS DYNAMICS IN A LOWLAND AFRICAN RAINFOREST: THE INFLUENCE OF ECTOMYCORRHIZAL TREES , 1997 .
[26] B. Drake,et al. MORE EFFICIENT PLANTS: A Consequence of Rising Atmospheric CO2? , 1997, Annual review of plant physiology and plant molecular biology.
[27] J. Stoorvogel,et al. The nutrient budgets of a watershed and its forest ecosystem in the Taï National Park in Cô d'Ivoire , 1997 .
[28] P. Vitousek,et al. Nutrient limitation and soil development: Experimental test of a biogeochemical theory , 1997 .
[29] G. Brümmer,et al. Effects of crystallinity of goethite: II. Rates of sorption and desorption of phosphate , 1997 .
[30] W. Schlesinger,et al. Mechanisms of Phosphorus Acquisition for Ponderosa Pine Seedlings under High CO 2 and Temperature , 1997 .
[31] H. Tiessen,et al. Limited applicability of the CENTURY model to highly weathered tropical soils , 1996 .
[32] C. Lovelock,et al. Growth responses to vesicular-arbuscular mycorrhizae and elevated CO2 in seedlings of a tropical tree, Beilschmiedia pendula , 1996 .
[33] R. Whittaker,et al. The Tropical Rain Forest: An Ecological Study, 2nd edn. , 1996 .
[34] E. Veenendaal,et al. Responses of West African Forest Tree Seedlings to Irradiance and Soil Fertility , 1996 .
[35] Yadvinder Malhi,et al. The use of eddy covariance to infer the net carbon dioxide uptake of Brazilian rain forest , 1996 .
[36] Martin Heimann,et al. Global and hemispheric CO2 sinks deduced from changes in atmospheric O2 concentration , 1996, Nature.
[37] G. Farquhar,et al. The CO 2 Dependence of Photosynthesis, Plant Growth Responses to Elevated Atmospheric CO 2 Concentrations and Their Interaction with Soil Nutrient Status. I. General Principles and Forest Ecosystems , 1996 .
[38] J. Melack,et al. Mass balance of major solutes in a rainforest catchment in the Central Amazon: Implications for nutrient budgets in tropical rainforests , 1996 .
[39] H. Lambers,et al. Response to phosphorus supply of tropical tree seedlings: a comparison between a pioneer species Tapirira obtusa and a climax species Lecythis corrugata. , 1996, The New phytologist.
[40] P. Friedlingstein,et al. On the contribution of CO2 fertilization to the missing biospheric sink , 1995 .
[41] John Moncrieff,et al. Carbon Dioxide Uptake by an Undisturbed Tropical Rain Forest in Southwest Amazonia, 1992 to 1993 , 1995, Science.
[42] Jerry M. Melillo,et al. The Role of Nitrogen in the Response of Forest Net Primary Production to Elevated Atmospheric Carbon Dioxide , 1995 .
[43] F. Chapin,et al. Responses to phosphorus of contrasting successional tree-seedling species from the tropical deciduous forest of Mexico , 1995 .
[44] Suan Chin Wong,et al. A simple calibrated model of Amazon rainforest productivity based on leaf biochemical properties , 1995 .
[45] Christopher Neill,et al. Nitrogen dynamics in soils of forests and active pastures in the western Brazilian Amazon Basin , 1995 .
[46] C. Hopkinson,et al. Effects of global change on carbon storage in tropical forests of South America , 1995 .
[47] P. Ciais,et al. A Large Northern Hemisphere Terrestrial CO2 Sink Indicated by the 13C/12C Ratio of Atmospheric CO2 , 1995, Science.
[48] Peter M. Vitousek,et al. Changes in soil phosphorus fractions and ecosystem dynamics across a long chronosequence in Hawaii. , 1995 .
[49] J. Fownes,et al. Phosphorus limitation of forest leaf area and net primary production on a highly weathered soil , 1995 .
[50] H. Tiessen,et al. The role of soil organic matter in sustaining soil fertility , 1994, Nature.
[51] D. J. Lodge,et al. The importance of nutrient pulses in tropical forests. , 1994, Trends in ecology & evolution.
[52] E. Frossard,et al. Glucose-1-phosphate and Myo-inositol Hexaphosphate Adsorption Mechanisms on Goethite , 1994 .
[53] J. Graham,et al. Growth Depression in Mycorrhizal Citrus at High-Phosphorus Supply (Analysis of Carbon Costs) , 1993, Plant physiology.
[54] C. Körner,et al. Responses to elevated carbon dioxide in artificial tropical ecosystems. , 1992, Science.
[55] Michael Garstang,et al. Saharan dust in the Amazon Basin , 1992 .
[56] B. Christensen,et al. Dynamics of soil organic matter as reflected by natural 13C abundance in particle size fractions of forested and cultivated oxisols , 1992 .
[57] I. Salcedo,et al. Nutrient and soil organic matter dynamics under shifting cultivation in semi-arid northeastern Brazil , 1992 .
[58] Lewis H. Ziska,et al. Potential effects of elevated CO2 and changes in temperature on tropical plants , 1991 .
[59] M. Forti,et al. Rainwater and throughfall chemistry in a “terra firme” rain forest: Central Amazonia , 1991 .
[60] R. Koide. Nutrient supply, nutrient demand and plant response to mycorrhizal infection. , 1991, The New phytologist.
[61] L. Bruijnzeel. Nutrient input–output budgets of tropical forest ecosystems: a review , 1991, Journal of Tropical Ecology.
[62] D. Clarkson,et al. KINETICS OF PHOSPHORUS UPTAKE BY THE GERM-TUBES OF THE VESICULAR-ARBUSCULAR MYCORRHIZAL FUNGUS, GIGASPORA MARGARITA , 1990 .
[63] E. Veneklaas. Nutrient fluxes in bulk precipitation and throughfall in two montane tropical rain forests, Colombia. , 1990 .
[64] W. W. McFee,et al. Phosphorus and Aluminum Release from a Spodic Horizon Mediated by Organic Acids , 1990 .
[65] L. Gardner. The role of rock weathering in the phosphorus budget of terrestrial watersheds , 1990 .
[66] P. Artaxo,et al. Aerosol characteristics and sources for the Amazon Basin during the wet season , 1990 .
[67] I. Jakobsen,et al. Carbon flow into soil and external hyphae from roots of mycorrhizal cucumber plants , 1990 .
[68] H. Lambers,et al. Root Respiration and Growth in Plantago major as Affected by Vesicular-Arbuscular Mycorrhizal Infection. , 1989, Plant physiology.
[69] A. S. Raghubanshi,et al. Microbial biomass acts as a source of plant nutrients in dry tropical forest and savanna , 1989, Nature.
[70] B. Whelan,et al. Testing a mechanistic model. VIII. The effects of time and temperature of incubation on the sorption and subsequent desorption of selenite and selenate by a soil , 1989 .
[71] H. Marschner. Mineral Nutrition of Higher Plants , 1988 .
[72] G. Robertson,et al. Nutrient mobility in variable- and permanent-charge soils , 1988 .
[73] P. Artaxo,et al. Composition and sources of aerosols from the Amazon Basin , 1988 .
[74] W. Parton,et al. Dynamics of C, N, P and S in grassland soils: a model , 1988 .
[75] Timothy J. Fahey,et al. Element interactions in forest ecosystems: succession, allometry and input-output budgets , 1988 .
[76] S. Hamilton,et al. Major element chemistry, weathering and element yields for the Caura River drainage, Venezuela , 1987 .
[77] P. Vitousek,et al. Cross‐system comparisons of soil nitrogen transformations and nitrous oxide flux in tropical forest ecosystems , 1987 .
[78] J. Proctor. Nutrient cycling in primary and old secondary rainforests , 1987 .
[79] D. López-Hernández,et al. Competitive Adsorption of Phosphate with Malate and Oxalate by Tropical Soils1 , 1986 .
[80] Michael Keller,et al. Emissions of N2O, CH4 and CO2 from tropical forest soils , 1986 .
[81] G. Lovett,et al. Atmospheric Deposition and Canopy Interactions of Major Ions in a Forest , 1986, Science.
[82] S. Oberbauer,et al. Effect of CO2‐enrichnient on seedling physiology and growth of two tropical tree species , 1985 .
[83] W. Brinkmann. Studies on hydrobiogeochemistry of a tropical lowland forest system , 1985 .
[84] J. Whipps. Effect of CO2 Concentration on Growth, Carbon Distribution and Loss of Carbon from the Roots of Maize , 1985 .
[85] G. Uehara,et al. The mineralogy, chemistry, and physics of tropical soils with variable charge clays (book review) , 1985 .
[86] E. Medina. NUTRIENT BALANCE AND PHYSIOLOGICAL PROCESSES AT THE LEAF LEVEL. , 1984 .
[87] C. Jordan,et al. Succession and Nutrient Dynamics Following Forest Cutting and Burning in Amazonia , 1984 .
[88] Peter M. Vitousek,et al. Litterfall, Nutrient Cycling, and Nutrient Limitation in Tropical Forests , 1984 .
[89] N. Barrow. On the reversibility of phosphate sorption by soils , 1983 .
[90] David J. Hicks,et al. The Ecology of Leaf Life Spans , 1982 .
[91] J. Hughes. High gradient magnetic separation of some soil clays from Nigeria, Brazil and Colombia.: I. The interrelationships of iron and aluminium extracted by acid ammonium oxalate and carbon , 1982 .
[92] P. Edwards,et al. STUDIES OF MINERAL CYCLING IN A MONTANE RAIN FOREST IN NEW GUINEA III. THE DISTRIBUTION OF MINERAL ELEMENTS IN THE ABOVE-GROUND MATERIAL , 1982 .
[93] W. McGill,et al. Comparative aspects of cycling of organic C, N, S and P through soil organic matter , 1981 .
[94] C. Jordan,et al. Tropical Rain Forests: Are Nutrients Really Critical? , 1981, The American Naturalist.
[95] F. S. Chapin,et al. The Mineral Nutrition of Wild Plants , 1980 .
[96] R. Duce,et al. Atmospheric Pathways of the Phosphorus Cycle , 1979 .
[97] G. Crozat. Sur l’émission d’un aérosol riche en potassium par la forêt tropicale , 1979 .
[98] C. Jordan,et al. Nutrient Retention by the Root Mat of an Amazonian Rain Forest , 1978 .
[99] D. S. Jenkinson,et al. THE TURNOVER OF SOIL ORGANIC MATTER IN SOME OF THE ROTHAMSTED CLASSICAL EXPERIMENTS , 1977 .
[100] P. Sánchez,et al. Properties and Management of Soils in the Tropics , 1977 .
[101] G. E. G. Mattingly. LABILE PHOSPHATE IN SOILS , 1975 .
[102] D. Mueller‐Dombois,et al. Ecology of Tropical and Subtropical Vegetation. , 1972 .
[103] F. Westin,et al. PHOSPHORUS FRACTIONS OF SOME VENEZUELAN SOILS AS RELATED TO THEIR STAGE OF WEATHERING , 1969 .
[104] J. Quirk,et al. THE MECHANISM OF PHOSPHATE ADSORPTION BY KAOLINITE, GIBBSITE, AND PSEUDOBOEHMITE: PART III. THE EFFECT OF TEMPERATURE ON ADSORPTION , 1966 .
[105] J. Quirk,et al. THE MECHANISM OF PHOSPHATE ADSORPTION BY KAOLINITE, GIBBSITE, AND PSEUDOBOEHMITE , 1966 .
[106] P. Nye,et al. The distribution of phosphorus in forest and savannah soils of the Gold Coast and its agricultural significance , 1957, The Journal of Agricultural Science.
[107] P. Richards,et al. The Tropical Rain Forest: An Ecological Study , 1953 .
[108] J. D. Dalton,et al. EFFECT OF ORGANIC MATTER ON PHOSPHATE AVAILABILITY , 1952 .
[109] Y. Malhi,et al. Productivity and carbon fluxes of tropical rain forests , 2001 .
[110] N. Barrow. The four laws of soil chemistry: the Leeper lecture 1998 , 1999 .
[111] D. Barrett,et al. Increased C-gain by an endemic Australian pasture grass at elevated atmospheric CO2 concentration when supplied with non-labile inorganic phosphorus , 1999 .
[112] W. McDowell,et al. Nitrogen stable isotopic composition of leaves and soil: Tropical versus temperate forests , 1999 .
[113] C. Lovelock,et al. Responses of communities of tropical tree species to elevated CO2 in a forest clearing , 1998, Oecologia.
[114] Peter M. Vitousek,et al. EXPERIMENTAL INVESTIGATION OF NUTRIENT LIMITATION OF FOREST GROWTH ON WET TROPICAL MOUNTAINS , 1998 .
[115] C. Lovelock,et al. Symbiotic vesicular-arbuscular mycorrhizae influence maximum rates of photosynthesis in tropical tree seedlings grown under elevated CO2 , 1997 .
[116] J. Melack,et al. Chemical composition and deposition of rain in the central Amazon, Brazil , 1997 .
[117] R. Houghton. Land-use change and terrestrial carbon: the temporal record , 1996 .
[118] J. Magid,et al. Dynamics of Organic Phosphorus in Soils under Natural and Agricultural Ecosystems , 1996 .
[119] K. Cameron,et al. Soil Science: Sustainable Production and Environmental Protection , 1996 .
[120] P. Meir. The exchange of carbon dioxide in tropical forest , 1996 .
[121] Peter M. Vitousek,et al. Both nitrogen and phosphorus limit plant production on young Hawaiian lava flows , 1996 .
[122] P. Reich,et al. Leaf carbon and nutrient assimilation and conservation in species of differing successional status in an oligotrophic Amazonian forest , 1995 .
[123] A. Martínez-Yrizar. Seasonally Dry Tropical Forests: Biomass distribution and primary productivity of tropical dry forests , 1995 .
[124] P. Kriedemann,et al. Leaf growth and photosynthetic response to nitrogen and phosphorus in seedling trees of Gmelina arborea , 1993 .
[125] Pamela A. Matson,et al. Nutrient limitations to plant growth during primary succession in Hawaii Volcanoes National Park , 1993 .
[126] J. Bäck,et al. Structural responses of needles of conifer seedlings to acid rain treatment , 1992 .
[127] S. K. De Datta,et al. Chemistry of Phosphorus Transformations in Soil , 1991 .
[128] D. Richter,et al. Soil Diversity in the Tropics , 1991 .
[129] M. Kirschbaum,et al. Photosynthetic responses to phosphorus nutrition in Eucalyptus grandis seedlings , 1990 .
[130] I. Mcpharlin,et al. PI Efflux and Influx by P-Adequate and P-Deficient Spirodela and Lemna , 1989 .
[131] Robert L. Sanford,et al. Nutrient Cycling in Moist Tropical Forest , 1986 .
[132] P. Brookes,et al. Phosphorus in the soil microbial biomass , 1984 .
[133] G. Parker. Throughfall and Stemflow in the Forest Nutrient Cycle , 1983 .
[134] E. Medina,et al. Productivity of Tropical Forests and Tropical Woodlands , 1983 .
[135] J. Syers,et al. The fate of phosphorus during pedogenesis , 1976 .
[136] D. Plucknett,et al. Quenching the High Phosphorus Fixation of Hawaiian Latosols 1 , 1966 .