Canopy Tree-Soil Interactions within Temperate Forests: Species Effects on Soil Carbon and Nitrogen

In a northwestern Connecticut forest, we quantified the carbon (C) and nitrogen (N) content of the forest floor and the top 15 cm of mineral soil and the rate of midsummer net N mineralization beneath six different tree species. There were large interspecific differences in forest floor depth and ma...

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Bibliographic Details
Published in:Ecological applications 1998-05, Vol.8 (2), p.440-446
Main Authors: Finzi, Adrien C., Van Breemen, Nico, Canham, Charles D.
Format: Article
Language:English
Subjects:
carbon
Coniferous forests
ecosystem
forest
Forest ecology
Forest litter
Forest soils
Maple sugar
Mineral soils
Nitrification
Nitrogen
Soil ecology
soils, forest
Trees
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Summary:In a northwestern Connecticut forest, we quantified the carbon (C) and nitrogen (N) content of the forest floor and the top 15 cm of mineral soil and the rate of midsummer net N mineralization beneath six different tree species. There were large interspecific differences in forest floor depth and mass, in the size and distribution of C and N pools at varying soil depths, and in rates of midsummer net N mineralization and nitrification. Forest floor mass ranged from 3.2 kg/m2to 11.0 kg/m2and was smallest beneath sugar maple and largest beneath hemlock. The pool size of C in the forest floor ranged from 1.1 kg/m2to 4.4 kg/m2while the N content of the forest floor ranged from 83 g/m2to 229 g/m2. Forest floor C and N pools were smallest beneath sugar maple and highest beneath hemlock. Soil C:N ratios (range: 14.8-19.5) were lower beneath sugar maple, red maple, and white ash than beneath beech, red oak, and hemlock, whereas the opposite was true of the midsummer rate of net N mineralization (range: 0.91-2.02 g·m-2·28 d-1). The rate of net nitrification was positively correlated with the rate of net N mineralization. Interspecific differences in litter production and quality explain the large differences among species in the size of the forest floor C and N pools and in net N mineralization rates. The differences in the size and distribution of C and N pools beneath the different species suggest that the mechanisms regulating the process of species replacement in these forests will mediate the effects of anthropogenic, environmental changes in soil C and N dynamics.
ISSN:1051-0761
1939-5582
DOI:10.1890/1051-0761(1998)008[0440:ctsiwt]2.0.co;2