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FIGURE 4-1 Some fate and transport processes in the subsurface and atmospheric environment.

FIGURE 4-1 Some fate and transport processes in the subsurface and atmospheric environment. FIGURE 4-2 Some fate and transport processes in the aquatic environment. FIGURE 4-3 Contaminant transfer through soil-water-air interfaces. FIGURE 4-4

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FIGURE 4-1 Some fate and transport processes in the subsurface and atmospheric environment.

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  1. FIGURE 4-1 Some fate and transport processes in the subsurface and atmospheric environment.

  2. FIGURE 4-2 Some fate and transport processes in the aquatic environment.

  3. FIGURE 4-3 Contaminant transfer through soil-water-air interfaces.

  4. FIGURE 4-4 Sources of fluids for the generation of landfill leachate.

  5. FIGURE 4-5 Water balance variables in the HELP model.

  6. FIGURE 4-6 Hydrologic cycle.

  7. FIGURE 4-7 Darcy’s experiment.

  8. FIGURE 4-8 Schematic of saturated flow in laboratory experiment.

  9. FIGURE 4-9 Bernoulli’s equation for flow through a pipe.

  10. FIGURE 4-10 Hydraulic heads in Darcy’s experiment.

  11. FIGURE 4-11 Darcy’s experiment revisited.

  12. FIGURE 4-12 Flow lines and equipotentials.

  13. FIGURE 4-13 Flow net for steady-state flow through a homogeneous embankment.

  14. FIGURE 4-14 Characteristic curves relating hydraulic conductivity and moisture content to pressure head for a naturally occurring sand soil.

  15. FIGURE 4-15 Schematic of mechanical dispersion.

  16. FIGURE 4-16 Effect of dispersion on contaminant transport.

  17. FIGURE 4-17 Plume migration affected by dispersion and source type. The arker the area, the higher the contaminant concentration.

  18. FIGURE 4-18 Effect of diffusion on contaminant transport with no advective transport.

  19. FIGURE 4-19 Schematic of fractured flow.

  20. FIGURE 4-20 Effect of high-permeability zone on contaminant transport.

  21. FIGURE 4-21 Movement of NAPL.

  22. FIGURE 4-22 Two-dimensional control volume.

  23. FIGURE 4-23 Finite difference.

  24. FIGURE 4-24 Simplified flow diagram representing general process of developing a transport model.

  25. FIGURE 4-25 Soil aggregates in subsurface domain.

  26. FIGURE 4-26 Partitioning of sorbate between solvent and sorbent.

  27. FIGURE 4-27 Two-stage sorption model.

  28. FIGURE 4-28 Desorption of sorbate.

  29. FIGURE 4-29 Sorption of lindane by unstripped and stripped soil.

  30. FIGURE 4-30 Variable sorption of trichloroethene on glacial till.

  31. FIGURE 4-31 Solubilities of metal hydroxides as a function of pH.

  32. FIGURE 4-32 Biological transformation of PCE under anaerobic conditions.

  33. FIGURE 4-33 Hydrolysis of chlorinated alkyl compounds.

  34. FIGURE 4-34 Reduction of sorption by cosolvation.

  35. FIGURE 4-35 Effect of the distribution coefficient on contaminant retardation during transport in a shallow groundwater flow system.

  36. FIGURE 4-36 A simplified, expanding box model.

  37. FIGURE 4-37 The effect of turbulent eddies on plumes (after Pendergast, 1984).124 (a) A large cloud in a uniform field of small eddies, (b) a small cloud in a uniform field of large eddies, (c) a cloud in a field of eddies of the same size as the cloud.

  38. FIGURE 4-38 Stable and unstable lapse rates.

  39. FIGURE 4-39 A gaussian distribution.

  40. FIGURE 4-40 Bivariate plume and plume cross section.

  41. FIGURE 4-41 PGT horizontal (crosswind) dispersion coefficient as a function of stability category and downwind distance.

  42. FIGURE 4-42 PGT vertical dispersion coefficient as a function of stability category and downwind distance.

  43. FIGURE 4-43 Two steps of estimating dispersion.

  44. FIGURE 4-44 Relative ground level concentration versus distance.

  45. FIGURE 4-45 Relative ground level concentration versus distance for various stability classes.

  46. FIGURE 4-46 Relative ground level concentration versus distance for various effective stack heights.

  47. EXAMPLE 4-7. FLOWNETFORAWATERTABLEAQUIFER.

  48. EXAMPLE 4-8. FINITE DIFFERENCE SOLUTION FOR DARCY’S EXPERIMENT.

  49. Hydrolysis of chlo-rinated organics involves exchange of the hydroxyl group with an anionic X on a carbon atom.

  50. 4-3. The groundwater contours are spaced at intervals of about 50 m.

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