A Streamflow Permanence Classification Model for Forested Streams That Explicitly Accounts for Uncertainty and Extrapolation

Jonathan D. Burnett; Kristin L. Jaeger; Sherri L. Johnson; Steven M. Wondzell; Jason B. Dunham; Matthew I. Barker; Emily Heaston; Nathan Chelgren; Michael G. Wing; Brian Staab; Michael E. Brown

doi:10.1029/2025wr040478

Water Resources Research (Jul 2025)

A Streamflow Permanence Classification Model for Forested Streams That Explicitly Accounts for Uncertainty and Extrapolation

Jonathan D. Burnett,
Kristin L. Jaeger,
Sherri L. Johnson,
Steven M. Wondzell,
Jason B. Dunham,
Matthew I. Barker,
Emily Heaston,
Nathan Chelgren,
Michael G. Wing,
Brian Staab,
Michael E. Brown

Affiliations

Jonathan D. Burnett: Pacific Northwest Research Station U.S. Forest Service Corvallis OR USA
Kristin L. Jaeger: U.S. Geological Survey Washington Water Science Center Tacoma WA USA
Sherri L. Johnson: Pacific Northwest Research Station U.S. Forest Service Corvallis OR USA
Steven M. Wondzell: Pacific Northwest Research Station U.S. Forest Service Corvallis OR USA
Jason B. Dunham: Forest and Rangeland Ecosystem Science Center U.S. Geological Survey Corvallis OR USA
Matthew I. Barker: U.S. Geological Survey Washington Water Science Center Tacoma WA USA
Emily Heaston: Forest and Rangeland Ecosystem Science Center U.S. Geological Survey Corvallis OR USA
Nathan Chelgren: Forest and Rangeland Ecosystem Science Center U.S. Geological Survey Corvallis OR USA
Michael G. Wing: College of Forestry Oregon State University Corvallis OR USA
Brian Staab: U.S. Forest Service Portland OR USA
Michael E. Brown: Bureau of Land Management Oregon/Washington Portland OR USA

DOI: https://doi.org/10.1029/2025wr040478
Journal volume & issue: Vol. 61, no. 7
pp. n/a – n/a

Abstract

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Abstract Accurate mapping of headwater streams and their flow status has important implications for understanding and managing water resources and land uses. However, accurate information is rare, especially in rugged, forested terrain. We developed a streamflow permanence classification model for forested lands in western Oregon using the latest light detection and ranging‐derived hydrography published in the National Hydrography Dataset. Models were trained using 2,518 flow/no flow field observations collected in late summer 2019–2021 across headwaters of 129 sub‐watersheds. The final model, the Western Oregon WeT DRy model, used Random Forest and 13 environmental covariates for classifying every 5‐m stream sub‐reach across 426 sub‐watersheds. The most important covariates were annual precipitation and drainage area. Model output included probabilities of late summer surface flow presence and were subsequently categorized into three streamflow permanence classes—Wet, Dry, and Ambiguous. Ambiguous denoted model probabilities and associated prediction intervals that extended over the 50% classification threshold between wet and dry. Model accuracy was 0.83 for sub‐watersheds that contained training data and decreased to 0.67 for sub‐watersheds that did not have observations of late summer surface flow. The model identified where predictions extrapolated beyond the domain characterized by the training data. The combination of spatially continuous estimates of late summer streamflow status along with uncertainty and extrapolation estimates provide critical information for strategic project planning and designing additional field data collection.

Published in Water Resources Research

ISSN: 0043-1397 (Print); 1944-7973 (Online)
Publisher: Wiley
Country of publisher: United States
LCC subjects: Geography. Anthropology. Recreation: Environmental sciences
Website: https://agupubs.onlinelibrary.wiley.com/journal/19447973

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