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Carbon, Nitrogen and Phosphorus Cycling in Forest Soils (2021)

Qualls, Robert G.

MDPI - Multidisciplinary Digital Publishing Institute

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Publication Date: 2024-04-05

Description: The majority of carbon stored in the soils of the world is stored in forests. The refractory nature of some portions of forest soil organic matter also provides the slow, gradual release of organic nitrogen and phosphorus to sustain long term forest productivity. Contemporary and future disturbances, such as climatic warming, deforestation, short rotation sylviculture, the invasion of exotic species, and fire, all place strains on the integrity of this homeostatic system of C, N, and P cycling. On the other hand, the CO2 fertilization effect may partially offset losses of soil organic matter, but many have questioned the ability of N and P stocks to sustain the CO2 fertilization effect.

Keywords: QH301-705.5 ; Q1-390 ; SD1-669.5 ; polyphenols ; aluminum accumulator ; near natural forest management ; chloroform fumigation extraction ; soil structure ; soil enzymes ; manure pelleting ; microbial biomass ; Oxisol ; biolability ; soil nutrients ; second production cycle ; PLFA ; pyrolysis ; Eucalyptus sp. ; Cunninghamia lanceolata plantation ; carbon ; the Three Gorges Reservoir ; revegetation ; carbon distribution index ; climate change ; seasons ; annual increment average ; topography ; humic substances ; litter N ; soil fertility ; climate zone ; nutrient cycling ; Daxing’an Mountains ; carbon mineralization ; nitrification ; 31P nuclear magnetic resonance spectroscopy (31P NMR) ; organic matter ; throughfall ; forest soil ; dissolved organic carbon (DOC) ; P species ; stoichiometric homeostasis ; dissolved organic matter (DOM) ; soil organic matter fraction ; variable-charge soils ; ammonium ; nitrate ; soil degradation ; soil P fractions ; seasonal trends ; ammonia-oxidizing bacteria ; nitrogen dynamics ; net primary productivity ; soil microbial communities ; beech forests ; soil pH ; wood volume ; temperature ; northern temperate ; multilevel models ; Pinus massoniana plantation ; ammonia-oxidizing archaea ; P stock ; stand density ; P resorption efficiency ; forest types ; soil greenhouse gas flux ; enzyme activities ; soil N ; alpine forest ; moisture gradient ; climate ; climatic factors ; soil available phosphorus ; microbial activity ; soil available nitrogen ; leaf N:P ratio ; stemflow ; Chamaecyparis forest ; charcoal ; gross nitrogen transformations ; principal component analyses ; information review ; manuring ; stand age ; tree-DOM ; thema EDItEUR::P Mathematics and Science::PS Biology, life sciences

Language: English

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Kinetics of the short-term consumption of chlorine by fulvic acid (1983)

Qualls, Robert G. ; Johnson, J. Donald

s.l. : American Chemical Society

Environmental science & technology 17 (1983), S. 692-698

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ISSN: 1520-5851

Source: ACS Legacy Archives

Topics: Chemistry and Pharmacology , Energy, Environment Protection, Nuclear Power Engineering

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1021/es00117a013

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Phosphorus Enrichment Affects Litter Decomposition, Immobilization, and Soil Microbial Phosphorus in Wetland Mesocosms (2000)

Qualls, Robert G. ; Richardson, Curtis J.

Springer

Soil Science Society of America journal 64 (2000), S. 799-808

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ISSN: 1435-0661

Source: Springer Online Journal Archives 1860-2000

Topics: Geosciences , Agriculture, Forestry, Horticulture, Fishery, Domestic Science, Nutrition

Notes: Typha domengensis Crantz) and sawgrass (Cladium jamaicense Pers.) litter into two sets of experimental channels into which controlled inputs of five different phosphate concentrations were added continuously. After 1 yr of incubation, litter was analyzed for C, P, N, Cu, Ca, and K content. Loss of C at the end of 1 yr increased linearly with increasing average PO4 content in the channels with a similar slope for both species of litter. Immobilization caused an absolute increase in P content of the litter up to approximately ninefold across the range of water P concentrations, while immobilization of N, Ca, and K did not vary with water P concentrations. During decomposition, litter exhibited a net uptake of Cu (a nutrient potentially limiting plant growth on peat soils). The microbial biomass P was up to nine times higher in the surface soil of the most enriched channel compared with the control, but this elevation in concentration was restricted to the upper 12 cm of soil.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/

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The influence of humic substances on the aerobic decomposition of submerged leaf litter (1990)

Qualls, Robert G. ; Haines, Bruce L.

Springer

Hydrobiologia 206 (1990), S. 133-138

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ISSN: 1573-5117

Keywords: fulvic acid ; litter decomposition ; swamps ; wetlands ; acidity ; humic

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Abstract Leaf material was incubated in flasks containing streamwater in which the pH and the concentration of isolated fulvic acid were varied independently of one another. Decomposition of the leaf material was slower at pH 4 than at pH 5 or 7, but the concentration of fulvic acid had no effect when the pH was held constant. At pH 5, 20 mg Cl−1 humic acid also had no effect on decomposition. High concentrations of dissolved fulvic acids may contribute to the slow decomposition of plant litter characteristic of many wetlands through their contribution to hydrogen ion activity, but we could find no evidence for other properties of fulvic acid which inhibit leaf litter decomposition.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00018639

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Effects of increased atmospheric CO2, temperature, and soil N availability on root exudation of dissolved organic carbon by a N-fixing tree (Robinia pseudoacacia L.) (2000)

Uselman, Shauna M. ; Qualls, Robert G. ; Thomas, Richard B.

Springer

Plant and soil 222 (2000), S. 191-202

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ISSN: 1573-5036

Keywords: CO2 enrichment ; carbon storage ; climate change ; dissolved organic carbon ; nitrogen fixation ; root exudate

Source: Springer Online Journal Archives 1860-2000

Topics: Agriculture, Forestry, Horticulture, Fishery, Domestic Science, Nutrition

Notes: Abstract Root exudation has been hypothesized as one possible mechanism that may lead to increased inputs of organic C into the soil under elevated atmospheric CO2, which could lead to greater long-term soil C storage. In this study, we analyzed exudation of dissolved organic C from the roots of seedlings of the N-fixing tree Robinia pseudoacacia L. in a full factorial design with 2 CO2 (35.0 and 70.0 Pa) × 2 temperature (26° and 30 °C during the day) × 2 N fertilizer (0 and 10.0 mM N concentration) levels. We also analyzed the decomposition rates of root exudate to estimate gross rates of exudation. Elevated CO2 did not affect root exudation of organic C. A 4 °C increase in temperature and N fertilization did, however, significantly increase organic C exudation rates. Approximately 60% of the exudate decomposed relatively rapidly, with a turnover rate of less than one day, while the remaining 40% decomposed more slowly. These results suggest that warmer climates, as predicted for the next century, may accelerate root exudation of organic C, which will probably stimulate rapid C cycling and may make a minor contribution to intermediate to more long-term soil C storage. However, as these losses to root exudation did not exceed 1.2% of the net C fixed by Robinia pseudoacacia, root exudation of organic C appears to have little potential to contribute to long-term soil C sequestration.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1023/A:1004705416108

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A test of a potential short cut in the nitrogen cycle: The role of exudation of symbiotically fixed nitrogen from the roots of a N-fixing tree and the effects of increased atmospheric CO2 and temperature (1999)

Uselman, Shauna M. ; Qualls, Robert G. ; Thomas, Richard B.

Springer

Plant and soil 210 (1999), S. 21-32

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ISSN: 1573-5036

Keywords: CO2 enrichment ; climate change ; dissolved organic nitrogen ; nitrogen cycle ; nitrogen fixation ; root exudate

Source: Springer Online Journal Archives 1860-2000

Topics: Agriculture, Forestry, Horticulture, Fishery, Domestic Science, Nutrition

Notes: Abstract N-fixing trees facilitate the growth of neighboring trees of other species. These neighboring species benefit from the simple presence of the N fixation symbiosis in their surroundings. Because of this phenomenon, it has been hypothesized that a change in atmospheric CO2 concentration may alter the role of N-fixing trees in their environment. It is thought that the role of N-fixing trees in ecosystems of the future may be more important since they may help sustain growth increases due to increased CO2 concentration in nitrogen limited forests. We examined: (1) whether symbiotically fixed N was exuded from roots, (2) whether a doubled atmospheric CO2 concentration would result in increased organic N exudation from roots, and (3) whether increased temperature or N availability affected N exudation from roots. This study analyzed exudation of dissolved organic N from the roots of seedlings of the N-fixing tree Robinia pseudoacacia L. in a full factorial design with 2 CO2 (35.0 and 70.0 Pa) × 2 temperature (26 or 30 °C during the day) × 2 N fertilizer (0 and 10.0 mM N concentration) levels. Trees with no other source of N except N fixation exuded about 1% to 2% of the fixed N through their roots as dissolved organic N. Increased atmospheric CO2 concentrations did not, however, increase N exudation rates on a per gram belowground biomass basis. A 4 °C increase in temperature and N fertilization did, however, significantly increase N exudation rates. These results suggest that exudation of dissolved organic N from roots or nodules of N-fixing trees could be a significant, but minor, pathway of transferring N to neighboring plants in a much more rapid and direct way than cycling through death, decomposition and mineralization of plant residues. And, while exudation rates of dissolved organic N from roots were not significantly affected by atmospheric CO2 concentration, the previously observed ‘CO2 fertilization effect’ on N-fixing trees suggests that N exudation from roots could play a significant but minor role in sustaining increases in forest growth, and thus C storage, in a CO2 enriched atmosphere.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1023/A:1004619509878

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