1. EXAMPLE Pathways of Liquid Effluents in Groundwater and Surface Water (Section 2.4.13 SAR)
FRAMES-2.0 Workshop
U.S. Nuclear Regulatory Commission
Bethesda, Maryland
November 15-16, 2007
Pacific Northwest National Laboratory
Richland, Washington

2. Purpose Demonstrate Hierarchical Modeling
SSAR assessment: instantaneous mixing, advection, retardation, decay
Modeling: mass balance, advection, dispersion, retardation, decay
Instantaneous release
Long-term release (20-yr leak)
Explore Conservative Assumptions
Full mixing over the Aquifer Depth
Largest Darcy Velocity
No Dispersion
Register and use an Excel Spreadsheet 2

3. Problem Description (direct quote from SAR)
“Reactor Coolant Storage Tank is postulated to rupture, and 80% of its liquid volume (92 m3) is assumed to be released in accordance with Branch Technical Position 11-6…Flow from the rupture is postulated to flood the building and migrate past the building containment structure and sump collection system and enter the subsurface at the top of the building slab…(V)ertical downward flow ensues. A pathway is created that would allow the entire 92 m3 to enter the groundwater system instantaneously.” 3

4. Problem Definition No vadose zone, aquifer only
Uses known tank concentrations
Instantaneously places 80% (not 100%) of the tank’s mass into only the aquifer’s effective pore space
Uses tank’s total liquid volume to estimate the plan view area of contamination
NOT an instantaneous release scenario, which requires mass balance checks on water and mass flux rates
Mixes contamination over the aquifer depth (conservative?)
Maximum Darcy velocity (noted as conservative)
Advection, Decay, and Retardation Only (noted as conservative)
No Dispersion (noted as conservative) 4

5. Fully Mixed With Dispersion Source Upper Aquitard Fully Mixed Plume
River
Plume
Upper Aquifer Unit
Fully
Mixed
Fully Mixed
Upper Aquitard
Upper Aquifer Unit
Plume
Source
River
With Dispersion 5

6. 6

7. Modules Source, Vadose Zone, and Aquifer Transport
FRAMES Constituent Database Selection
Source (User-defined source term) – WFF Vadose Zone Module
MEPAS 5.0 Aquifer Module
MEPAS 5.0 River Module
Exposure/Intake/Risk
MEPAS 5.0 Exposure Pathways Module
MEPAS 5.0 Receptor Intakes Module
MEPAS 5.0 Health Impacts Module 7

8. Registering an Excel Worksheet
Model Input
Registering an Excel Worksheet
(separate presentation) 8

9. 9

10. 10

11. 11

12. Constituent
Database 12

13. “Source-Term” Module 13

14. Aquifer Module 14

15. River Module 15

16. Chronic Exposure Module16

17. Intake Module
Impacts Module 17

18. Output Results 18

19. Constituent Concentrations in Aquifer at River’s Edge
pCi/mL
pCi/mL
pCi/mL
Years 19

20. Comments & Investigations
Modeling provides us with an opportunity to more fully understand the problem. SAR case ignores mass balance of water flux rate.
Maximum Darcy Velocity is conservative – Reduce SZ Darcy Velocity one order of magnitude
Fully mixed condition is conservative – Increase the aquifer depth 20

21. Check to see if a maximum saturated zone Darcy velocity is conservative:
Reduce the saturated zone Darcy velocity by an order of magnitude (i.e., 1/10th) 21

22. Reduced by 1/10th 22

23. Reduced by 1/10th 23

24. Reduced by 1/10th 24

25. Reduced by 1/10th 25

26. Constituent Concentrations in Aquifer at River’s Edge at 1/10th the Darcy Velocity
pCi/mL
pCi/mL
pCi/mL
Years 26

27. Hierarchical Modeling Results27

28. Check to see if fully mixed conditions in the aquifer is conservative:
Increase the aquifer thickness.
This case was not run, but the modeling can provide insight on how aquifer depth can impact the conservative assumption. 28

29. Rule-of-Thumb Relationships29

30. Rule-of-Thumb Relationship Definitions30

31. Summary
Many important factors determine whether scenarios and assumptions are conservative
Interdependencies between parameters
Duration of release
Time of concentration
Water mass balance
Contaminant mass balance 31