Prediction of lake depth across a 17-state region in the United States

TitlePrediction of lake depth across a 17-state region in the United States
Publication TypeJournal Article
Year of Publication2016
AuthorsOliver, S. K., Soranno P. A., Fergus C. E., Wagner T., Winslow L. A., Scott C. E., Webster K. E., Downing J. A., and Stanley E. H.
JournalInland Waters
Volume6
Issue3
Number of Pages314-324
Type of ArticleArticle
Reprint Number2044-2041
LTER Accession NumberWOS:000384067400004
Keywordslake depth; mixed model; morphology; regional scale; topography, spatial scale; surface-area; phosphorus; catchment; sample; map
Abstract

Lake depth is an important characteristic for understanding many lake processes, yet it is unknown for the vast majority of lakes globally. Our objective was to develop a model that predicts lake depth using map-derived metrics of lake and terrestrial geomorphic features. Building on previous models that use local topography to predict lake depth, we hypothesized that regional differences in topography, lake shape, or sedimentation processes could lead to region-specific relationships between lake depth and the mapped features. We therefore used a mixed modeling approach that included region-specific model parameters. We built models using lake and map data from LAGOS, which includes 8164 lakes with maximum depth (Z(max)) observations. The model was used to predict depth for all lakes >= 4 ha (n = 42 443) in the study extent. Lake surface area and maximum slope in a 100 m buffer were the best predictors of Z(max). Interactions between surface area and topography occurred at both the local and regional scale; surface area had a larger effect in steep terrain, so large lakes embedded in steep terrain were much deeper than those in flat terrain. Despite a large sample size and inclusion of regional variability, model performance (R-2 = 0.29, RMSE = 7.1 m) was similar to other published models. The relative error varied by region, however, highlighting the importance of taking a regional approach to lake depth modeling. Additionally, we provide the largest known collection of observed and predicted lake depth values in the United States.

DOI10.5268/IW-6.3.957
Print Copy LocationInland Waters