Effects of roof and rainwater characteristics on copper concentrations in roof runoff

Copper sheeting is a common roofing material used in many parts of the world. However, copper dissolved from roof sheeting represents a source of copper ions to watersheds. Researchers have studied and recently developed a simple and efficient model to predict copper runoff rates. Important input pa...

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Bibliographic Details
Published in:Environmental monitoring and assessment 2012-05, Vol.184 (5), p.2797-2804
Main Authors: Bielmyer, Gretchen K., Arnold, W. Ray, Tomasso, Joseph R., Isely, Jeff J., Klaine, Stephen J.
Format: Article
Language:English
Subjects:
Aluminum
Atmospheric Protection/Air Quality Control/Air Pollution
Copper
Copper - analysis
Correlation
Earth and Environmental Science
Ecology
Ecotoxicology
Environment
Environmental Management
Environmental Monitoring
Housing - statistics & numerical data
Mathematical analysis
Mathematical models
Models, Chemical
Monitoring/Environmental Analysis
Precipitation
Rain
Rain - chemistry
Roofing
Roofs
Runoff
Runoff rates
Stormwater management
Studies
Test systems
Water Pollutants, Chemical - analysis
Water quality
Watersheds
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Summary:Copper sheeting is a common roofing material used in many parts of the world. However, copper dissolved from roof sheeting represents a source of copper ions to watersheds. Researchers have studied and recently developed a simple and efficient model to predict copper runoff rates. Important input parameters include precipitation amount, rain pH, and roof angle. We hypothesized that the length of a roof also positively correlates with copper concentration (thus, runoff rates) on the basis that runoff concentrations should positively correlate with contact time between acidic rain and the copper sheet. In this study, a novel system was designed to test and model the effects of roof length (length of roof from crown to the drip edge) on runoff copper concentrations relative to rain pH and roof angle. The system consisted of a flat-bottom copper trough mounted on an apparatus that allowed run length and slope to be varied. Water of known chemistry was trickled down the trough at a constant rate and sampled at the bottom. Consistent with other studies, as pH of the synthetic rainwater decreased, runoff copper concentrations increased. At all pH values tested, these results indicated that run length was more important in explaining variability in copper concentrations than was the roof slope. The regression equation with log-transformed data ( R 2  = 0.873) accounted for slightly more variability than the equation with untransformed data ( R 2  = 0.834). In log-transformed data, roof angle was not significant in predicting copper concentrations.
ISSN:0167-6369
1573-2959
DOI:10.1007/s10661-011-2152-1