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Elise A. Striz, Hydrologist USEPA ORD National Risk Management Research Laboratory Ground Water and Ecosystems Restoration Div. Ada, OK US EPA Optimal.

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Presentation on theme: "Elise A. Striz, Hydrologist USEPA ORD National Risk Management Research Laboratory Ground Water and Ecosystems Restoration Div. Ada, OK US EPA Optimal."— Presentation transcript:

1 Elise A. Striz, Hydrologist USEPA ORD National Risk Management Research Laboratory Ground Water and Ecosystems Restoration Div. Ada, OK US EPA Optimal Well Locator (OWL): A Screening Tool for Evaluating Locations of Monitoring Wells October 6, 2004 Region 5 ORD Product Expo

2 Optimal Well Locator (OWL) Version 1.2 2 Ponniah Srinivasan, CertainTech, Elise A. Striz, US EPA, John T. Wilson, US EPA, and Daniel F. Pope, Dynamac

3 1. What is the variation in ground water flow magnitude and direction at the site over time? 2.How does the variation in ground water flow magnitude and direction affect the plume migration at the site over time? 3.Are the existing monitoring wells able to intercept the plume? Where is the best place to put a new monitoring well? OWL Questions 3

4 What is the variation in ground water flow magnitude and direction at the site over time? Question 1 4

5 Ground Water Flow Field 10/30/98 R 2 =0.96 i =0.013 10/30/98 5

6 i =0.021 R 2 =0.77 12/21/98 Ground Water Flow Field 12/21/98 6

7 i =0.028 R 2 =0.90 1/11/99 Ground Water Flow Field 1/11/99 7

8 i =0.020 R 2 =0.87 3/29/99 Ground Water Flow Field 3/29/99 8

9 Question 2 How does the variation in ground water flow magnitude and direction affect the plume migration at the site over time? 9

10 t = 6 years k = 514 ft/yr v =.45 R =1 No decay a x =30 ft a y =3 ft C 0 =125 mg/l Source width Y = 30 ft Plume Migration Path 10/30/98 10

11 t = 6 years k = 514 ft/yr v =.45 R =1 No decay a x =30 ft a y =3 ft C 0 =125 mg/l Source width Y = 30 ft Plume Migration Path 12/21/98 11

12 t = 6 years k = 514 ft/yr v =.45 R =1 No decay a x =30 ft a y =3 ft C 0 =125 mg/l Source width Y = 30 ft Plume Migration Path 1/11/99 12

13 t = 6 years k = 514 ft/yr v =.45 R =1 No decay a x =30 ft a y =3 ft C 0 =125 mg/l Source width Y= 30 ft Plume Migration Path 3/29/99 13

14 Question 3 Are the existing monitoring wells able to intercept the plume? Where is the best place to put a new monitoring well? 14

15 Red : 10-100 mg/l Existing MW coverage good Yellow: 1-10 mg/l Existing MW coverage sparse Green: 0.1-1.0 mg/l One existing MW Average Composite Plume 15

16 Dark Blue : 0-60 ft to nearest MW (best) Light Blue: 60-120 ft to nearest MW Green: 120-180 ft to nearest MW Yellow: 180-240 ft to nearest MW Red: 240-300 ft to nearest MW (worst) Minimum Distance to Nearest Monitoring Well: Measure of MW Coverage 16

17 Red : 10,000-100,000 best place for new wells Yellow: 1000-10,000 another good place for new wells Dark Blue: 1-10 existing well may not be necessary here Well Optimal Location Factor (WOLF) 17

18 A Scaled Basemap : The OWL program requires the user to have a scaled basemap of the site in electronic form. The program accepts raster (*.bmp, *.tif) and vector (*.dwg, *.shp) electronic formats. OWL Input Data 18

19 Well Locations: OWL requires the well locations to be in consistent ( x, y ) coordinates from a rectangular grid based on the map dimensions. These data must be saved and imported into the program from a spreadsheet (Excel, Lotus). OWL Input Data 19

20 Ground Water Elevations: The OWL program requires routine measurements of ground water levels (preferably monthly or quarterly) from a monitoring well network demonstrating good spatial coverage of the site. These data must be saved and imported into the program from a spreadsheet file (Excel, Lotus). OWL Input Data 20

21 Subsurface Geology: The monitoring wells used to provide water level data for OWL must be screened in the same aquifer. The aquifer should be homogeneous, isotropic and of constant thickness. OWL Input Data 21

22 Site Characterization: The contamination and hydrologic characteristics of the aquifer at the site must entered into the OWL program. This information includes: a. contaminant source width b. contaminant source concentration c. contaminant retardation factor d. contaminant half-life e. aquifer hydraulic conductivity f. effective porosity g. longitudinal/transverse dispersivity OWL Input Data 22

23 OWL Assumptions/Limitations Assumes simple ground water flow regimes in which water table surface can be represented by a linear plane. Not suited to sites with significant surface water/groundwater interaction, pumping/injection wells, ground water divides, or vertical gradients. Assumes 1D advective and dispersive contaminant transport. 23

24 1.PC with MS Windows 95, 98, NT, ME, 2000, XP 2. 32 MB RAM, 40 MB disk space 3. Spreadsheet software (Excel or Lotus) OWL Computer Requirements 24

25 OWL Learning Curve 1.Time to learn software: 1 day 2.Time to work up site data: 1hour-1/2 day 3.Time to enter data and run program: 1 hour 25

26 OWL Potential Applications and Users Leaking Underground Storage Tank Sites Monitored Natural Attenuation Sites State Regulators Site Consultants 26

27 The OWL program and user’s manual is available for download from the EPA Center for Subsurface Modeling Support (CSMoS) web site at http://www.epa.gov/ada/ csmos/models.html Technical support for OWL is provided by the EPA Center for Subsurface Modeling Support (CSMoS). OWL Program Availability and Tech Support 27

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