Comprehensive network hydraulic scaling datasets and associated resources (discharge, channel length surveys, watershed metadata, blueline network shapefiles and reference images)


A newer version of this resource https://doi.org/10.4211/hs.7cde55a84f164caca332c9671c884581 is available that replaces this version.
An older version of this resource http://www.hydroshare.org/resource/bf484f2dad4b4b1692b3416d6cf4281f is available.
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Created: Apr 01, 2021 at 6:10 a.m.
Last updated: Apr 01, 2021 at 6:31 a.m. (Metadata update)
Published date: Apr 01, 2021 at 6:13 a.m.
DOI: 10.4211/hs.21e2e71b44d542ed92bb5b1e0fe176c4
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Sharing Status: Published
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Abstract

Wetted channel networks expand and contract throughout the year. Direct observation of this process can be made by multiple intensive surveys of a catchment throughout the year. Godsey et al. (2014) suggest that the extent of the wetted channel network scales with discharge at the outlet by a power law (L = αQ^β). Using this relationship, we developed a framework to assess variability in the extent of wetted channels as a function of beta, β, and the variability in streamflow, Q (Lapides et al. 2021). This resource includes the empirical basis for the study and data compiled from the literature and maps.

1 - Channel length survey data (csv files)
2 - Discharge time series data (csv files)
3 - Watershed metadata (csv file)
4 - Blueline network files (pdf, png, and shp files)

This collection includes all watersheds where at least three channel length surveys have been conducted and where a corresponding discharge time series dataset is available. The requirement of a minimum of three channel length surveys stems from the data requirements to find alpha, α, and β for the power law relationship between discharge and stream network length for headwater catchments (Godsey et al. 2014). Data for 14 watersheds worldwide are included, along with watershed metadata, reference maps, shapefiles and a composite of USGS blueline stream network imagery with terrain for watersheds of interest in the United States.

Methods used to process the datasets or create other assets in this collection are included in the abstracts or additional metadata for each of the four resources listed above. Python code used to process data, compute variables, and create graphics is available at: https://zenodo.org/record/4057320

Subject Keywords

Coverage

Spatial

Coordinate System/Geographic Projection:
WGS84 EPSG:4326
Coordinate Units:
['Decimal degrees']
North Latitude
51.8800°
East Longitude
8.7300°
South Latitude
35.0500°
West Longitude
-123.7300°

Temporal

Start Date:
End Date:

Collection Contents

Add Title Type Owners Sharing Status Remove
4 - Blueline network files Resource Christine Leclerc Published
2 - Discharge time series data Resource Christine Leclerc Published
3 - Watershed metadata Resource Christine Leclerc Published
1 - Channel length survey data Resource Christine Leclerc Published

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This resource is referenced by Lapides, D., Leclerc, C. D., Moidu, H., Dralle, D., & Hahm, W. J. (2020, August 14). Variability of headwater stream network extents controlled by flow regime and network hydraulic scaling. https://doi.org/10.31223/osf.io/mc6np
This resource updates and replaces a previous version Leclerc, C. D., D. A. Lapides, H. Moidu, D. N. Dralle, W. J. Hahm (2021). Comprehensive network hydraulic scaling datasets and associated resources (discharge, channel length surveys, watershed metadata, blueline network shapefiles and reference images), HydroShare, http://www.hydroshare.org/resource/bf484f2dad4b4b1692b3416d6cf4281f
This resource has been replaced by a newer version Leclerc, C. D., D. A. Lapides, H. Moidu, D. N. Dralle, W. J. Hahm (2021). Comprehensive network hydraulic scaling dataset and associated resources (discharge, channel length surveys, watershed metadata, blueline network shapefiles, reference images), HydroShare, https://doi.org/10.4211/hs.7cde55a84f164caca332c9671c884581
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The content of this resource is derived from Lapides, DA, Leclerc, CD, Moidu, H, Dralle, DN, Hahm, WJ. Variability of stream extents controlled by flow regime and network hydraulic scaling. Hydrological Processes. 2021; 35:e14079. https://doi-org.proxy.lib.sfu.ca/10.1002/hyp.14079

Credits

Funding Agencies

This resource was created using funding from the following sources:
Agency Name Award Title Award Number
Natural Sciences and Engineering Research Council of Canada Undergraduate Student Research Award

How to Cite

Leclerc, C. D., D. A. Lapides, H. Moidu, D. N. Dralle, W. J. Hahm (2021). Comprehensive network hydraulic scaling datasets and associated resources (discharge, channel length surveys, watershed metadata, blueline network shapefiles and reference images), HydroShare, https://doi.org/10.4211/hs.21e2e71b44d542ed92bb5b1e0fe176c4

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