Book Chapter10.2136/SSSABOOKSER5.2.C42
Nitrogen Mineralization, Immobilization, and Nitrification
Stephen C. Hart,John M. Stark,Eric A. Davidson,Mary K. Firestone +3 more
- 11 Sep 2018
- pp 985-1018
1K
TL;DR: The biogeochemical cycling of N in ecosystems can be divided into an external and an internal N cycle as mentioned in this paper, and the internal cycle consists of those processes that convert N from one chemical form to another or transfer N between ecosystem pools.
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Abstract: The biogeochemical cycling of N in ecosystems can be divided into an external and an internal N cycle. The external cycle includes those processes that add or remove N from ecosystems, such as: dinitrogen (N2) fixation, dry and wet N deposition, N fertilization, N leaching, runoff erosion, denitrification, and ammonia volatilization. The internal N-cycle consists of those processes that convert N from one chemical form to another or transfer N between ecosystem pools. Processes of the internal N-cycle include: plant assimilation of N, return of N to soil in plant litterfall and root turnover, N mineralization (the conversion of organic N to inorganic N), microbial immobilization of N (the uptake of inorganic N by microorganisms), and nitrification (the production of nitrite {N02-} and nitrate {N03-} from ammonium {NH/} or organic N) (Fig. 42-1). The significance of internal N-cycling processes can be illustrated by comparing the rates of these processes relative to external N-cycling rates. For example, Paul and Clark (1989) estimate that the sum of all output fluxes of the external N-cycle globally is about 0.25 x 1015 g-N yr1, while net N mineralization in soils is more than 14 times this amount (about 3.5 x 1015 g-N ye1). However, because net N mineralization is the difference between actual N mineralization and microbial immobilization of N, gross N mineralization rates may be over two orders of magnitude greater than all output fluxes of N combined (see below).
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Citations
Nitrification and denitrification derived N2O production from a grassland soil under application of DCD and Actilith F2
P. Merino,J. M. Estavillo,Gerardo Besga,Miriam Aparecida de Oliveira Pinto,Carmen González-Murua +4 more
TL;DR: In this paper, the relative contribution of nitrification and denitrification to N2O production was investigated by means of soil incubations with acetylene in a mixed clover/ryegrass sown sward 5 days after application of a mineral fertiliser (calcium ammonium nitrate) or an organic one (cattle slurry) with and without the addition of the nitrification inhibitor dicyandiamide (DCD) and the commercial slurry additive Actilith-F2.
50
“Hotspots” and “Hot Moments” of Denitrification in Urban Brownfield Wetlands
TL;DR: The influence of hydrology and soil properties on disproportionately high (hot) rates of nitrate (NO3 −) removal via denitrification has been relatively well established as mentioned in this paper.
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Mortality hotspots: Nitrogen cycling in forest soils during vertebrate decomposition
TL;DR: In this paper, the authors developed a comprehensive view of temporal changes in soil biogeochemical cycling during vertebrate decay, and provided a systems-level synthesis of N redistribution during animal decay and has significant implications for our understanding of nutrient turnover rates and dynamics in terrestrial ecosystems.
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No‐net‐loss not met for nutrient function in freshwater marshes: recommendations for wetland mitigation policies
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TL;DR: In this paper, the authors compare indicators of plant and microbial-mediated functions, as well as abiotic (e.g., soil character, hydrology) and biotic structure, between 10 created or restored and 5 natural freshwater depressional wetlands in central Ohio, USA.
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Seasonal changes in nitrification potential associated with application of N fertilizer and compost in maize systems of southwest Michigan
TL;DR: In this paper, the authors measured the effect of several management practices on nitrification potentials via an amended slurry method, shaken for 24h at 25°C. Management practices included substitution of compost for N fertilizer, use of a rotation in place of continuous maize and the addition of cover crops.
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References
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TL;DR: In this paper, the authors examine both how the biogeochemistry of the nitrogen cycle could cause limitation to develop, and how nitrogen limitation could persist as a consequence of processes that prevent or reduce nitrogen fixation.
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Biochemical Ecology of Nitrification and Denitrification
W. Verstraete,D. D. Focht +1 more
- 01 Jan 1977
TL;DR: In terms of the global fluxes between aerial and terrestrial-aquatic systems, the simplified nitrogen cycle can be envisioned as a triangle where the only biologically reversible reaction occurs between ammonium and nitrate.
933
Diffusion method to prepare soil extracts for automated nitrogen-15 analysis
TL;DR: In this article, a diffusion method was developed for preparing soil KCl extracts for 15NH+4 and 15NO-3 analyses, which is ideal for preparing samples having low N mass (50-200 µg N) with no cross contamination.
690
Methodology for studying fluxes of soil mineral-N in situ
TL;DR: In this article, a methodology for studying fluxes of mineral-N in soils, based on sequential soil coring and in situ exposure of largely undisturbed soil columns confined within metal or PVC tubes is described and evaluated.
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