Modeling leaching as a decomposition process in humid montane forests

Forests in the White Mountain region (New Hampshire, USA) range from northern hardwoods and pine at low elevations to spruce-fir at middle elevations, subalpine fir, and krummholz on mountain peaks. We studied landscape-scale effects of gradients in forest cover type, litter chemistry, rates of litt...

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Bibliographic Details
Published in:Ecology (Durham) 1997-09, Vol.78 (6), p.1844-1860
Main Authors: Currie, William S., Aber, John D.
Format: Article
Language:English
Subjects:
Animal and plant ecology
Animal, plant and microbial ecology
Biodegradation
BIOGEOCHEMISTRY
Biological and medical sciences
Carbon
carbon stocks
CICLO BIOGEOQUIMICO
CO2 fluxes
Coniferous forests
CYCLE BIOGEOCHIMIQUE
CYCLING
Decomposition
DEGRADACION
DEGRADATION
dissolved organic carbon
dissolved organic nitrogen
Ecology
Forest cover
Forest ecology
FOREST LITTER
Forests
Forests and forestry
Fundamental and applied biological sciences. Psychology
GEOCHEMISTRY
GEOCHIMIE
Geographic Information System (GIS)
GEOGRAPHIC INFORMATION SYSTEMS
GEOQUIMICA
Hardwood forests
Hardwoods
HIGHLANDS
HOJARASCA FORESTAL
humic substances
Humus
landscape
Leaching
LITIERE FORESTIERE
litter quality
Mixed forests
NEW HAMPSHIRE
Nitrogen
nutrient cycling
REGION D'ALTITUDE
SISTEMAS DE INFORMACION GEOGRAFICA
Synecology
SYSTEME D'INFORMATION GEOGRAPHIQUE
Temperature
Terrestrial ecosystems
White Mountains, New Hampshire
ZONA DE MONTANA
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Summary:Forests in the White Mountain region (New Hampshire, USA) range from northern hardwoods and pine at low elevations to spruce-fir at middle elevations, subalpine fir, and krummholz on mountain peaks. We studied landscape-scale effects of gradients in forest cover type, litter chemistry, rates of litter input (including fine woody litter), temperature, and moisture on forest-floor pools and input-output fluxes of C and N. We coupled a new model of decomposition processes to a Geographic Information System (GIS) and applied it in 10-ha cells in the White Mountain National Forest. We sought to synthesize current understanding of forest-floor leachate qualities and quantities in humid forests with measured changes in carbon fractions ("lignin," "cellulose," and "extractives") in decomposing litter. We included N dynamics as transfers of N among C fractions, including the production of dissolved organic N in leachate from the forest floor. We calibrated fluxes of dissolved organic C and N (DOC and DON) to measurements from two stands at the Harvard Forest, Massachusetts, USA. We calibrated rates of humus decay to two sites at the Hubbard Brook Experimental Forest. By including leaching as a mechanism of mass loss from the forest floor, we were able to calculate CO2 mineralization fluxes by difference. Predicted masses of forest floor were higher and peaked over a broader elevational range in spruce-fir forest than in hardwoods, due primarily to a slower decay rate of humus in coniferous forests. DOC and DON fluxes were higher in coniferous forests, while CO2 fluxes were higher in hardwood forests. Predicted residence times for C in the forest floor were longer, and organic N concentrations were higher, in spruce-fir forests than in hardwood forests. Along a generalized elevational ecotone from hardwood to spruce-fir forests in the region, predicted mass and N in the forest floor increased and DOC and DON fluxes increased, while CO2 fluxes decreased.
ISSN:0012-9658
1939-9170
DOI:10.1890/0012-9658(1997)078[1844:MLAADP]2.0.CO;2