Forest Age Influences In-stream Ecosystem Processes in Northeastern US

• Published in: Ecosystems (New York) Vol. 20; no. 5; pp. 1058 - 1071
• Main Authors: Bechtold, H. A., Rosi, E. J., Warren, D. R., Keeton, W. S.
• Format: Journal Article
• Language: English
• Published: New York Springer Science + Business Media 01.08.2017; Springer US; Springer; Springer Nature B.V
• Subjects: Age; Age composition; Biomass; Biomedical and Life Sciences; Canopies; Catchments; Climate change; Climatic changes; Creeks & streams; Drainage; Ecology; Ecosystems; Environmental Management; Forests; Geoecology/Natural Processes; Human influences; Hydrology/Water Resources; Irradiance; Life Sciences; Metabolism; Nutrient availability; Nutrient concentrations; Nutrient dynamics; Nutrient loading; Nutrient retention; Nutrient uptake; Nutrients; Old growth forests; Original Articles; Physiological aspects; Plant Sciences; Pollution load; Primary production; Riparian environments; Riparian forests; Streams; Zoology; Northeastern states; headwater streams; forest structure; NO; metabolism; NH; nutrient uptake; light availability; PO; climate change
• ISSN: 1432-9840; 1435-0629
• DOI: 10.1007/s10021-016-0093-9

A disturbance or natural event in forested streams that alter available light can have potential consequences for nutrient dynamics and primary producers in streams. In this study, we address how functional processes (primary production and nutrient uptake) in stream ecosystems respond to changes in forest canopy structure. We focus on differences in incoming irradiance, nutrient uptake (NO₃, NH₄, and PO₄) and open-channel metabolism seasonally in 13 forested streams that drain forests with different canopy structures (10 to > 300 years old) in the northeastern United States. Light irradiance was related to forest age in a U-shaped pattern, with light being the greatest in both young open forests (< 50 years old) and older growth forests (> 245 years old), whereas the darkest conditions were found in the secondary growth middleaged forests (80–158 years old). Streams that had adjacent open or old-growth riparian forest had similar conditions with greater standing stock biofilm biomass (chl a), and elevated ER in October compared to streams with middle-aged riparian forests. Compared to all sites, streams with oldgrowth riparian forest had the greatest in-stream primary production rates (GPP) and elevated background nutrient concentrations, and to a lesser degree, increased nutrient retention and uptake (V f). Streams draining older forests tended to be more productive and retentive than middle-aged forests, likely due to increased light availability and the age and structure of surrounding forest canopies. Middle-aged forests had the least variation in response variables compared to streams in young and old-growth riparian forests, likely a result of uniform canopy conditions. As the structure of widespread middle-aged forests in NE US is altered by loss of specific tree species, climate change, and/or human activity, it will impact in-stream production and nutrient dynamics and may ultimately alter nutrient loading in downstream catchments.