Checking for non-preferred file/folder path names (may take a long time depending on the number of files/folders) ...
This resource contains some files/folders that have non-preferred characters in their name. Show non-conforming files/folders.
This resource contains content types with files that need to be updated to match with metadata changes. Show content type files that need updating.
Authors: |
|
|
---|---|---|
Owners: |
|
This resource does not have an owner who is an active HydroShare user. Contact CUAHSI (help@cuahsi.org) for information on this resource. |
Type: | Resource | |
Storage: | The size of this resource is 12.5 KB | |
Created: | Dec 11, 2020 at 9:55 p.m. | |
Last updated: | Dec 19, 2020 at 9:01 a.m. (Metadata update) | |
Published date: | Dec 11, 2020 at 10:10 p.m. | |
DOI: | 10.4211/hs.76ebc18852cc41e48d4ee83902bc0a7d | |
Citation: | See how to cite this resource | |
Content types: | Single File Content |
Sharing Status: | Published |
---|---|
Views: | 1298 |
Downloads: | 56 |
+1 Votes: | Be the first one to this. |
Comments: | No comments (yet) |
Abstract
Watershed metadata was collected for 14 watersheds from studies where channel length survey data was presented. For variables not found in the publications associated with the channel length surveys, additional sources are referenced. These sources are included in the notes column. Variables without sources were calculated, as described in the Additional Metadata section below. Examples of calculated values include, q_avg_mm_per_day, beta, and l_avg_km.
For Python packages, modules, and functions used to find calculated values, please see the associated GitHub repository: https://zenodo.org/record/4057320
Subject Keywords
Coverage
Spatial
Content
Additional Metadata
Name | Value |
---|---|
r2 | R-squared the proportion of variance (represented by a number from 0 to 1 in value) for the dependent variable explained by the independent variable. Here, the independent variable is discharge and the dependent variable is stream network extent. |
beta | Scaling exponent for power function that characterizes the relationship between discharge and stream length, no units. Beta (β) is the scaling exponent in the power relation L = αQ^β. Discharge (Q) and drainage density (L) from at least three channel length surveys are fit to a power law model to obtain β. |
cv_l | Coefficient of variation for length time series, no units as mean and standard deviation are in same units. Found by dividing standard deviation by the mean. |
cv_q | Coefficient of variation for discharge time series is unitless as mean and standard deviation are in same units. Found by dividing standard deviation by the mean. |
q_ url | Discharge time series URL |
q_stop | Discharge time series stop date in YYYY-MM-DD format |
beta_sd | Standard deviation for beta, no units. Calculated during parameter fitting of power law model. |
q_start | Discharge time series start date in units of YYYY-MM-DD format |
ws_name | Watershed name |
ws_soil | Watershed soil |
gauge_id | Gauge station ID, as available |
bl_topquad | Was a 7.5’ topographic map found for this watershed? Y/N |
gauge_name | Gauge station name |
ws_bedrock | Watershed bedrock |
ws_climate | Watershed climate per Köppen system. See code repository for Köppen climate classification tool used to find climate zones. |
bl_l_per_km | Persistent channel network length in units of km. Georeferenced streamline segments measured in ArcMap. |
bl_l_tot_km | Persistent and intermittent channel network length in units of km, as depicted by USGS 7.5' blueline maps. Georeferenced streamline segments were measured in ArcMap. Dashed lines for intermittent streams are measured only for the solid extent in ArcMap. To get the full length of intermittent stream in the maps, the gaps in a relatively straight 5.8 cm length of intermittent streamline was measured. Based on the ratio between segment length and extent of gaps, intermittent streamline lengths measured by ArcMap were multiplied by a factor of 1.34 to arrive at an estimate for the full length of intermittent stream segments. |
l_sd_km_km2 | Standard deviation for stream network length time series in units of km/km2. Calculated from inferred network extent timeseries. |
ws_area_km2 | Watershed area in units of km2 |
ws_name_sub | Sub-watershed identifier |
ws_elev_avg_m | Watershed mean elevation in units of m |
bl_topquad_url | URL for 7.5’ topographic map found for this watershed, as available |
q_sd_mm_per_day | Standard deviation for discharge time series in units of mm/day. |
alpha_units_vary | Scaling factor for power function that characterizes the relationship between discharge and stream length; Units vary as a function of the power law exponent β: (mm/day)^β/(km/km^2) |
gauge_lat_decdeg | Gauge station latitude in units of decimal degrees |
gauge_lon_decdeg | Gauge station longitude in units of decimal degrees |
q_avg_mm_per_day | Average daily discharge in units of mm/day |
alpha_sd_units_vary | Standard deviation for alpha; Units vary and can be (km/km^2)/(mm/day). Alpha (α) is the scaling factor in the power relation L = αQ^β. Discharge (Q) and drainage density (L) from at least three channel length surveys are fed into the model to obtain alpha. |
bl_l_per_km_per_km2 | Persistent channel network drainage density in units of km/km^2. Found by dividing wetted channel extent by watershed area. |
bl_l_tot_km_per_km2 | Persistent and intermittent channel network drainage density in units of km/km^2. Found by dividing wetted channel extent by watershed area. |
ws_precip_mm_per_yr | Watershed annual average precipitation in units of mm/year |
src_of_noncalculated_vals | Additional sources for metadata table values |
Related Resources
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. (2020). 3 - Watershed metadata, HydroShare, https://doi.org/10.4211/hs.a3b06e4eafd1489699933a81226aafce |
This resource has been replaced by a newer version | Leclerc, C. D. (2020). 3 - Watershed metadata, HydroShare, https://doi.org/10.4211/hs.68290b979a0d4dcbbb03cef36114db47 |
The content of this resource is derived from | U.S. Geological Survey: Thompson Creek near Clayton, ID, https://waterdata.usgs.gov/monitoring-location/13297330/#parameterCode= 00060, accessed 05 August 2020, 2020bf. |
The content of this resource is derived from | UK Centre for Ecology and Hydrology: Ray at Grendon Underwood, https://nrfa.ceh.ac.uk/data/station/meanflow/39017, accessed 29 July 2020, 2020. |
The content of this resource is derived from | Zimmer, M. A., Runoff Generation Across Ephemeral To Perennial Piedmont Catchments. PhD in Earth and Ocean Sciences. Duke University. 2017. |
The content of this resource is derived from | PRISM. PRISM Climate Group 30-Year Normals. Corvallis, OR: Oregon State University. Retrieved from http://prism.oregonstate.edu. 2010. |
The content of this resource is derived from | U.S. Geological Survey: Blackbird Creek near Cobalt, ID, https://waterdata.usgs.gov/monitoring-location/13306336/#parameterCode= 00060, accessed 05 August 2020, 2020ca. |
The content of this resource is derived from | Hunsaker, C.: SSCZO – Streamflow / Discharge – KREW, Bull Creek – 2003-2010), https://doi.org/http://www.hydroshare.org/resource/d6d8b2a6e5604629b1192233646dfea1, updated 21 November 2019, 2019a. |
The content of this resource is derived from | US Forest Service: Caspar Creek Experimental Watershed Study, SFC - Tributary South Fork (1963-1995) data, https://doi.org/https://www.fs.fed.us/psw/topics/water/caspar/data/map/sfc.shtml, updated 18 August 1998, 1998b. |
The content of this resource is derived from | US Forest Service: Caspar Creek Experimental Watershed Study, NFC - Tributary North Fork (1963-1995) data, https://doi.org/https://www.fs.fed.us/psw/topics/water/caspar/data/map/nfc.shtml, updated 18 August 1998, 1998a. |
The content of this resource is derived from | Miniat, C. F., Laseter, S. H., Swank, W. T., and Vose, J. M.: Daily streamflow data for watersheds at Coweeta Hydrologic Lab, North Carolina, https://doi.org/10.2737/RDS-2016-0025, updated 10 February 2020, 2016. |
The content of this resource is derived from | Zimmer, M.: Duke Forest Research Watershed Data Archives, https://doi.org/https://doi.org/10.2737/RDS-2016-0025, updated 19 July 2019, 2017. |
The content of this resource is derived from | Blyth, K. and Rodda, J.: A stream length study, Water Resources Research, 9, 1454–1461, 1973. |
The content of this resource is derived from | U.S. Geological Survey: Elder C Nr Branscomb CA, https://waterdata.usgs.gov/monitoring-location/11475560/#parameterCode=00060, accessed 28 July 2020, 2020ah. |
The content of this resource is derived from | Edwards, P. J. and Wood, F.: Fernow Experimental Forest daily streamflow, https://doi.org/https://doi.org/10.2737/RDS-2011-0015, updated 9 January 2020, 2011 |
The content of this resource is derived from | USDA Forest Service, Northern Research Station: Hubbard Brook Experimental Forest: Daily Streamflow by Watershed, 1956 - present, https://portal.edirepository.org/nis/mapbrowse?scope=knb-lter-hbr&identifier=2, updated 25 June 2020, 2020. |
The content of this resource is derived from | Hunsaker, C.: SSCZO – Streamflow / Discharge – Providence – (2003-2010), https://doi.org/https://www.hydroshare.org/resource/180f67282b4149ca8d4f41b2438257eb/, updated 21 November 2019, 2019b. |
The content of this resource is derived from | U.S. Geological Survey: Sagehen C Nr Truckee CA, https://waterdata.usgs.gov/monitoring-location/10343500/#parameterCode=00060, accessed 29 July 2020, 2020gd. |
The content of this resource is derived from | Stähli, M.: Longterm hydrological observatory Alptal (central Switzerland), https://www.envidat.ch/#/metadata/ longterm-hydrological-observatory-alptal-central-switzerland, updated 10 April 2018, 2018. |
The content of this resource is derived from | U.S. Geological Survey: Sixmile Creek at Bethel Grove NY, https://waterdata.usgs.gov/monitoring-location/04233300/#parameterCode= 00060, accessed 29 July 2020, 2020hg |
The content of this resource is derived from | U.S. Geological Survey (2020d): Johnson Creek at Yellow Pine ID, https://waterdata.usgs.gov/monitoring-location/13313000/#parameterCode=00060, accessed 29 July 2020, 2020. |
The content of this resource is derived from | U.S. Geological Survey (2020e): Meadow Creek near Stibnite, ID, https://waterdata.usgs.gov/monitoring-location/13310850/#parameterCode=00060, accessed 29 July 2020, 2020. |
The content of this resource is derived from | U.S. Geological Survey (2020f): MF Salmon River at Mouth near Shoup, ID, https://waterdata.usgs.gov/monitoring-location/13310199/#parameterCode=00060, accessed 29 July 2020, 2020. |
The content of this resource is derived from | Godsey, S. E. and Kirchner, J. W.: Dynamic, discontinuous stream networks: hydrologically driven variations in active drainage density,flowing channels and stream order, Hydrological Processes, 28, 5791–5803, https://doi.org/10.1002/hyp.10310, 00010, 2014. |
The content of this resource is derived from | Chen, D. and Chen, H. W.: Using the Köppen classification to quantify climate variation and change: An example for 1901–2010, Environ-mental Development, 6, 69–79, 2013. |
The content of this resource is derived from | Laseter, Stephanie H.; Ford, Chelcy R.; Vose, James M.; Swift, Lloyd W. Jr. 2012. Long-term temperature and precipitation trends at the Coweeta Hydrologic Laboratory, Otto, North Carolina, USA. Hydrology Research 43(6):890-901. |
The content of this resource is derived from | Whiting, J. A. and Godsey, S. E.: Discontinuous headwater stream networks with stable flowheads, Salmon River basin, Idaho, HydrologicalProcesses, 30, 2305–2316, https://doi.org/10.1002/hyp.10790, _eprint: https://onlinelibrary.wiley.com/doi/pdf/10.1002/hyp.10790, 2016. |
The content of this resource is derived from | Crooks, S. M., Kay, A. L., and Reynard, N. S.: Regionalised impacts of climate change on flood flows: hydrological models, catchments and calibration, Milestone report 1, available at: http://randd.defra.gov.uk/Document.aspx?Document= FD2020_8853_TRP.pdf (last access: 21 September 2020), 2010 |
The content of this resource is derived from | van Meerveld, H. J. I.: Expansion and contraction of the flowing stream network alter hillslope flowpath lengths and the shape of the travel time distribution, Hydrology and Earth System Sciences, 23, 4825–6604834, https://doi.org/10.5194/hess-23-4825-2019, publisher: Copernicus GmbH, 2019. |
The content of this resource is derived from | Shaw,S.B.: Investigating the linkage between streamflow recession rates and channel network contraction in a mesoscale catchment in New York state, Hydrological Processes, 30, 479–492, https://doi.org/10.1002/hyp.10626, _eprint: https://onlinelibrary.wiley.com/doi/pdf/10.1002/hyp.10626, 2016. |
The content of this resource is derived from | National Oceanic and Atmospheric Administration. “Data Tools: 1981-2010 Normals.” 1981-2010 Normals | Data Tools | Climate Data Online (CDO) | National Climatic Data Center (NCDC), www.ncdc.noaa.gov/cdo-web/datatools/normals. 2020. |
The content of this resource is derived from | Jensen, C. K., McGuire, K. J., and Prince, P. S.: Headwater stream length dynamics across four physiographic provinces of the Appalachian Highlands, Hydrological Processes, 31, 3350–3363, https://doi.org/10.1002/hyp.11259, _eprint:https://onlinelibrary.wiley.com/doi/pdf/10. 2017. |
The content of this resource is derived from | Lovill, S. M., Hahm, W. J., and Dietrich, W. E.: Drainage from the Critical Zone: Lithologic Controls on the Persistence and Spatial Extent of Wetted Channels during the Summer Dry Season, Water Resources Research, 54, 5702–5726, https://doi.org/10.1029/2017WR021903. 2017. |
The content of this resource is derived from | U.S. Geological Survey: Patterson Mountain CA 2018, U.S. Geological Survey, https://prd-tnm.s3.amazonaws.com/StagedProducts/Maps/USTopo/PDF/CA/CA_Patterson_Mountain_20180829_TM_geo.pdf, accessed 29 July 2020, 2020. |
The content of this resource is derived from | U.S. Geological Survey: Mathison Peak CA 2018, U.S. Geological Survey, https://prd-tnm.s3.amazonaws.com/StagedProducts/Maps/USTopo/PDF/CA/CA_Mathison_Peak_20181107_TM_geo.pdf, accessed 29 July 2020, 2020. |
The content of this resource is derived from | U.S. Geological Survey: Prentiss NC 2019, U.S. Geological Survey, https://prd-tnm.s3.amazonaws.com/StagedProducts/Maps/USTopo/PDF/NC/NC_Prentiss_20190729_TM_geo.pdf, accessed 29 July 2020, 2020. |
The content of this resource is derived from | U.S. Geological Survey: Northwest Durham NC 2019, U.S. Geological Survey, https://prd-tnm.s3.amazonaws.com/StagedProducts/Maps/USTopo/PDF/NC/NC_Northwest_Durham_20190807_TM_geo.pdf, accessed 29 July 2020, 2020. |
The content of this resource is derived from | U.S. Geological Survey: Southwest Durham NC 2019, U.S. Geological Survey, https://prd-tnm.s3.amazonaws.com/StagedProducts/Maps/USTopo/PDF/NC/NC_Southwest_Durham_20190729_TM_geo.pdf, accessed 29 July 2020, 2020. |
The content of this resource is derived from | U.S. Geological Survey: Cahto Peak CA 2018, U.S. Geological Survey, https://prd-tnm.s3.amazonaws.com/StagedProducts/Maps/USTopo/PDF/CA/CA_Cahto_Peak_20180912_TM_geo.pdf, accessed 29 July 2020, 2020. |
The content of this resource is derived from | U.S. Geological Survey: Lincoln Ridge CA 2018, U.S. Geological Survey, https://prd-tnm.s3.amazonaws.com/StagedProducts/Maps/USTopo/PDF/CA/CA_Lincoln_Ridge_20180912_TM_geo.pdf, accessed 29 July 2020, 2020. |
The content of this resource is derived from | U.S. Geological Survey: Parsons WV 2019, U.S. Geological Survey, https://prd-tnm.s3.amazonaws.com/StagedProducts/Maps/USTopo/PDF/WV/WV_Parsons_20191209_TM_geo.pdf, accessed 29 July 2020, 2020. |
The content of this resource is derived from | U.S. Geological Survey: Woodstock NH 2018, U.S. Geological Survey, https://prd-tnm.s3.amazonaws.com/StagedProducts/Maps/USTopo/PDF/NH/NH_Woodstock_20180707_TM_geo.pdf, accessed 29 July 2020, 2020. |
The content of this resource is derived from | U.S. Geological Survey: Dinkey Creek CA 2018, U.S. Geological Survey, https://prd-tnm.s3.amazonaws.com/StagedProducts/Maps/USTopo/PDF/CA/CA_Dinkey_Creek_20180829_TM_geo.pdf, accessed 29 July 2020, 2020. |
The content of this resource is derived from | U.S. Geological Survey: Hobart Mills CA 2018, U.S. Geological Survey, https://prd-tnm.s3.amazonaws.com/StagedProducts/Maps/USTopo/PDF/CA/CA_Hobart_Mills_20180907_TM_geo.pdf, accessed 29 July 2020, 2020. |
The content of this resource is derived from | U.S. Geological Survey: Independence Lake CA 2018, U.S. Geological Survey, https://prd-tnm.s3.amazonaws.com/StagedProducts/Maps/USTopo/PDF/CA/CA_Independence_Lake_20180907_TM_geo.pdf, accessed 29 July 2020, 2020. |
The content of this resource is derived from | U.S. Geological Survey: Dryden NY 2019, U.S. Geological Survey, https://prd-tnm.s3.amazonaws.com/StagedProducts/Maps/USTopo/PDF/NY/NY_Dryden_20190925_TM_geo.pdf, accessed 29 July 2020, 2020. |
The content of this resource is derived from | U.S. Geological Survey: Dave Lewis Peak ID 2020, U.S. Geological Survey, https://prd-tnm.s3.amazonaws.com/StagedProducts/Maps/USTopo/PDF/ID/ID_Dave_Lewis_Peak_20200421_TM_geo.pdf, accessed 6 August 2020, 2020. |
The content of this resource is derived from | Environment Agency, Environment Agency - Catchment Data Explorer, https://environment.data.gov.uk/catchment-planning/ManagementCatchment/3012/Summary, updated 17 September 2020, 2020. |
Title | Owners | Sharing Status | My Permission |
---|---|---|---|
Comprehensive network hydraulic scaling datasets and associated resources (discharge, channel length surveys, watershed metadata, blueline network shapefiles and reference images) | Christine Leclerc | Published | Open Access |
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
This resource is shared under the Creative Commons Attribution CC BY.
http://creativecommons.org/licenses/by/4.0/
Comments
There are currently no comments
New Comment