Phosphorus Availability in Acid Organic Soils of the Lower North Carolina Coastal Plain

Walbridge, Mark R.

doi:10.2307/1941561

Cited by 151 publications

(122 citation statements)

References 56 publications

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“…This extract was then filtered and analyzed for TP using persulfate digestion in order to estimate the microbial + labile P fraction. Microbial + labile P concentrations were corrected to account for the incomplete extraction (43.3%; Qualls and Richardson 1995) of microbial P using this method (Walbridge 1991). The second extractant was 0.1 mol L 21 NaOH.…”

Section: Methodsmentioning

confidence: 99%

Characterization of suspended particles in Everglades wetlands

Noe

Harvey

Saiers

2007

Limnology & Oceanography

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We report the concentration, phosphorus (P) and nitrogen (N) content, and size and chemical fractionation of fine suspended particles (0.2-100 mm) and colloids (3 kilodalton [kDa]-0.1 mm) in the surface water of Everglades wetlands along regional and P-enrichment gradients. Total suspended sediment concentrations ranged from 0.7 to 2.7 mg L 21 . Total particulate P concentrations increased from 0.05 mmol L 21 to 0.31 mmol L 21 along the Penrichment gradient. Particles contained from 20% to 43% of total P but ,12% of total N in surface water. Dissolved (,0.2 mm) organic N contained about 90% of total N, with the 3-100-kDa colloidal size class containing the most N of any size class. The 0.45-2.7-mm size fraction held the most particulate P at all sites, whereas particulate N was most abundant in the 2.7-10-mm size class at most sites. Standard chemical fractionation of particles identified acid-hydrolyzable P as the most abundant species of particulate P, with little reactive or refractory organic P. Sequential chemical extraction revealed that about 65% of total particulate P was microbial, while about 25% was associated with humic and fulvic organic matter. The size and chemical fractionation information suggested that P-rich particles mostly consisted of suspended bacteria. Suspended particles in Everglades wetlands were small in size and had low concentrations, yet they stored a large proportion of surface-water P in intermediately reactive forms, but they held little N.

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Section: Methodsmentioning

confidence: 99%

Characterization of suspended particles in Everglades wetlands

Noe

Harvey

Saiers

2007

Limnology & Oceanography

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“…Existing publications (7,10,(13)(14)(15) provide limited insight into broad biogeographic leaf N and P patterns. For example, alpine and arctic herbaceous plant species had higher leaf N and P when examined in colder, rather than warmer, habitats (9,16,17), but leaf N and P were either similar (17,18) or lower (19) for given tree species in colder than warmer sites, and forest communities can have regionally lower (15) or higher (20) leaf N with increasing temperatures.…”

mentioning

confidence: 99%

Global patterns of plant leaf N and P in relation to temperature and latitude

Reich

Oleksyn

2004

Proc. Natl. Acad. Sci. U.S.A.

1,754

238

1,665

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A global data set including 5,087 observations of leaf nitrogen (N) and phosphorus (P) for 1,280 plant species at 452 sites and of associated mean climate indices demonstrates broad biogeographic patterns. In general, leaf N and P decline and the N͞P ratio increases toward the equator as average temperature and growing season length increase. These patterns are similar for five dominant plant groups, coniferous trees and four angiosperm groups (grasses, herbs, shrubs, and trees). These results support the hypotheses that (i) leaf N and P increase from the tropics to the cooler and drier midlatitudes because of temperature-related plant physiological stoichiometry and biogeographical gradients in soil substrate age and then plateau or decrease at high latitudes because of cold temperature effects on biogeochemistry and (ii) the N͞P ratio increases with mean temperature and toward the equator, because P is a major limiting nutrient in older tropical soils and N is the major limiting nutrient in younger temperate and high-latitude soils. N itrogen (N) and phosphorus (P) are generally considered the two most limiting elements to terrestrial vegetation, but global patterns in soil N and P limitation or plant N and P status have not been well characterized (1-10). Here we use a large data set, consisting of 5,087 observations of leaf N and P for 1,280 plant species at 452 sites, to explore global patterns of leaf N and P (expressed herein per unit of dry biomass, mg͞g) and their ratio (N͞P) in relation to broad-scale variability in geography, temperature, and other climatic factors. Such patterns may provide insights for fields as diverse as ecological stoichiometry, global carbon modeling, and macroecology (1,11,12). Given the specific functions of N and P in leaves, N in proteins important in all enzymatic activity, and P in protein synthesis, it would be surprising if temperature did not influence N and P, but the potential ways such influence could occur are complex. Biogeographic gradients in N and P could occur due to temperature effects on plant physiology or soil biogeochemistry, as well as due to geographic patterns of soil substrate age, all of which could be further influenced by correlated variation in plant species composition or trait variation (1-10), disease incidence, herbivory, and other variables. Growing season temperature and length are likely important aspects of the thermal environment that influence geographic patterns in leaf N and P. Other climatic factors, such as precipitation, could also influence patterns of leaf N and P.Existing publications (7, 10, 13-15) provide limited insight into broad biogeographic leaf N and P patterns. For example, alpine and arctic herbaceous plant species had higher leaf N and P when examined in colder, rather than warmer, habitats (9, 16, 17), but leaf N and P were either similar (17, 18) or lower (19) for given tree species in colder than warmer sites, and forest communities can have regionally lower (15) or higher (20) leaf N with increasing temperatures. In...

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“…Richardson and Gibbons (1993) summarized Walbridge's (1986) soil chemistry work on pocosins and bay forests in North Carolina and found results similar to those of Bridgham and Richardson (1993) described above.…”

Section: Soilsmentioning

confidence: 61%

An Old-Growth Definition for Evergreen Bay Forests and Related Seral Communities

McKevlin¹

1996

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Phosphorus Availability in Acid Organic Soils of the Lower North Carolina Coastal Plain

Cited by 151 publications

References 56 publications

Characterization of suspended particles in Everglades wetlands

Characterization of suspended particles in Everglades wetlands

Global patterns of plant leaf N and P in relation to temperature and latitude

An Old-Growth Definition for Evergreen Bay Forests and Related Seral Communities

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