Add to ORKGAbstract: Anthropogenic and industrial emissions have resulted in historically high levels of acidic deposition into central Appalachian forests. Despite the reduction in acidic inputs due to legislation curbing industrial emissions in the United States, continued N deposition may impact forest ecosystems. Soil and foliar samples were collected from four high elevation red spruce sites along a modeled gradient of historic N deposition. The three most abundant tree species at all sites, Acer rubrum L., Betula alleghaniensis Britt., and Picea rubens Sarg., were sampled. Bulk soil beneath the canopies of individual trees were collected from the top 15-cm and separated into organic and mineral fractions for analysis. Mehlich-III soil extracts o...
The extent to which atmospheric N deposition is enhancing primary production and CO2sequestration al...
Deposition of N and S has increased since the 1950s in most European countries and N accumulates in ...
Anthropogenic activities have altered both nitrogen (N) and phosphorus (P) cycles across the globe. ...
Abstract: Anthropogenic and industrial emissions have resulted in historically high levels of acidic...
Since the colonization of North America by Europeans, ecosystems in Appalachia and across the contin...
Atmospheric deposition of reactive nitrogen (N) can have a strong influence on patterns of carbon (C...
One set of hypotheses offered to explain the decline of red spruce (Picea rubens Sarg.) in eastern N...
Nutrient distributions, concentrations, and fluxes in two red spruce (Picearubens Sarg.) stands in ...
This research explored effects of ecosystem change from increased atmospheric nitrogen (N) depositio...
This report summarizes progress in three years of field research designed to evaluate biological and...
Excess nitrogen (N) in terrestrial ecosystems can arise from anthropogenically-increased atmospheric...
Many forested systems of the eastern US are becoming significantly nitrogen (N) saturated due to chr...
High-elevation red spruce-Fraser fir forests in the Southern Appalachian mountains: 1) receive among...
AbstractExcess nitrogen (N) in terrestrial ecosystems can arise from anthropogenically-increased atm...
Soil acidification has constituted an important ecological threat to forests in Central Europe since...
The extent to which atmospheric N deposition is enhancing primary production and CO2sequestration al...
Deposition of N and S has increased since the 1950s in most European countries and N accumulates in ...
Anthropogenic activities have altered both nitrogen (N) and phosphorus (P) cycles across the globe. ...
Abstract: Anthropogenic and industrial emissions have resulted in historically high levels of acidic...
Since the colonization of North America by Europeans, ecosystems in Appalachia and across the contin...
Atmospheric deposition of reactive nitrogen (N) can have a strong influence on patterns of carbon (C...
One set of hypotheses offered to explain the decline of red spruce (Picea rubens Sarg.) in eastern N...
Nutrient distributions, concentrations, and fluxes in two red spruce (Picearubens Sarg.) stands in ...
This research explored effects of ecosystem change from increased atmospheric nitrogen (N) depositio...
This report summarizes progress in three years of field research designed to evaluate biological and...
Excess nitrogen (N) in terrestrial ecosystems can arise from anthropogenically-increased atmospheric...
Many forested systems of the eastern US are becoming significantly nitrogen (N) saturated due to chr...
High-elevation red spruce-Fraser fir forests in the Southern Appalachian mountains: 1) receive among...
AbstractExcess nitrogen (N) in terrestrial ecosystems can arise from anthropogenically-increased atm...
Soil acidification has constituted an important ecological threat to forests in Central Europe since...
The extent to which atmospheric N deposition is enhancing primary production and CO2sequestration al...
Deposition of N and S has increased since the 1950s in most European countries and N accumulates in ...
Anthropogenic activities have altered both nitrogen (N) and phosphorus (P) cycles across the globe. ...
