1. Time of Travel

2. American Water Charleston intake on the Elk River Charleston 1,000,864 - 998,984 = 1880 seconds or 31 minutes

3. Delineation rules 1.Five hour travel time 2.Include tributaries but do not cross over watershed bnds 3.Buffer mainstem 1,000ft 4.Buffer tributaries 500ft 5.Buffer intake 1,000ft downstream

4. Statewide extents ZCCs were done for all 142 surface water intakes in WV

5. Vulnerability analysis Other data sources  National pollution discharge elimination system sites  Landfills  Superfund sites (CERCLIS)  Hazardous and solid waste sites (RCRIS)  Toxic release inventory sites  Coal dams  Abandoned mine land locations  Animal feed lots  Major highways  Railroads

6. Zones of critical concern Defined as a 5 hour travel time above the surface water intake. GOAL: To use an equation that included stream velocity Source: U. S. Geological Survey. 1996. “Prediction of Travel Time and Longitudinal Dispersion in Rivers and Streams.” Water- Resources Investigations Report 96-4013.

7. Critical variables Drainage area (D a ) Reach slope (S) Mean annual river discharge (Q a ) Discharge at time of measurement (Q) Peak velocity (V p )

8. Equations

9. Equations

10. An ArcToolbox approach…

11. Time of travel

14. Mannings N

16. Mannings n

17. Mannings n summary table of streams

18. Time of travel

22. Time of travel calculations This tool creates a raster whose cells measure the length of time in seconds, that it takes water to flow across it and then accumulates the time from the cell to the outlet of the watershed. The tool uses Manning's Equation to determine the velocity of water flowing across the surface in feet per second. The tool then inverts that value to get seconds per horizontal unit (meters or feet, depending on projection), and then uses the FlowLength Tool using the Travel Time grid with the DOWNSTREAM option to determine the flow time from each cell to the outlet. Water velocity is calculated as a function of hydraulic radius, Manning's N and slope. Using a DEM as a source, flow direction, flow accumulation and slope (percent) is calculated. Using flow accumulation, each cell is assigned one of three flow regimes. Slopes are processed so that there are no cells with zero slopes.Landcover is used to assign flow N and R values to non channelized cells. When calculating the slope along vector drainage channels the elevation is masked to include only those DEM cells that are up or downstream of the flow path. This removes the influence of the side channel areas which typically have higher slopes than the channel itself. Users can use various landcover sources but these must be matched to the N and R table that is stored in the /data folder in this distribution. The N and R table must contain one record for each of the raster valeus in the landcover grid and there must be the same fields in that table for the program to work. R and N values are assigned based on landcover and flow regime. Hydraulic Radius is calucated using: (X)a + Y where: X = hydraulic radius factor 1 (User setting, 0.0032 default) a = drainage area in square miles (calculated from low Accumulation) Y = hydraulic radius factor 2 (User setting, 1.7255 default) Velocity is calculated as: vel(feet/second) = (1.49 * Hydraulic Radius^0.667 * slope^0.5) / Mannings N Travel Time across individual cells is calculated as: Once travel time across individual cells is known then Travel Time is calculated for each cell to the outlet of the basin using the FlowLength command using the cell-based travel time grid as an impedence factor and the DOWNSTREAM option.

23. Ongoing efforts Senate Bill (SB) 373 which was signed into law on April 1, 2014 and effective June 6, 2014 outlines specific requirements on how source water Zones of Critical Concerns (ZCC) are to be defined. Improvements: 1.Updated elevation datasets at a better temporal and spatial scale 2.Improved regional curves for channel characteristics 3.Stream flow modeling methods to better estimate ungauged locations

24. Questions / Comments?