Model/
Workspace
|
Name
|
Brief Description
|
| CFITM/CFITM |
Example1 |
Example 2A: Chromium (Column Number 4) - Semi-Finite System |
| |
Example2 |
Example 2B: Chromium (Column Number 4) - Finite Sysem |
| CFITIM/CFITIM |
Example1 |
Generated data, Nonequilibrium model |
| |
Example2 |
Example 2D: Tritiated water (EXP. 5-2); Nonequilibrim model |
| |
Example3 |
Example 2H: Tritiated water (EXP. 5-2); Linear adsorption model |
| |
Fig79a |
Tritium effluent curve from Glendale clay loam; Nonequilibrim model |
| |
Fig79b |
Boron effluent [exp. 3-1, van Genuchten, 1974]; Nonequilibrim model |
| CHAIN/CHAIN |
Nitrogen |
Nitrogen chain [Cho, 1972] |
| |
Radionuc |
Radionuclide transport |
| CXTFIT/Direct |
Fig51 |
First-order nonequilibrium model, effect of beta and omega |
| |
Fig52 |
First-order nonequilibrium model, effect of beta and f |
| |
Fig71 |
Fig.7-1: The deterministic CDE (BVP+PVP) |
| |
Fig72a |
Fig.7-2a: Flux vs. (resident) conc. for the IVP, Cf(Z) (a) P=2 (b) P=10 |
| |
Fig72b |
Fig.7-2b: (Flux) vs. resident conc. for the IVP, Cf(Z) (a) P=2 (b) P=10 |
| |
Fig75 |
Fig.7-5: Nonequilibrium one-site CDE (beta=1/R,omega=0.08, 0.2, 1.0, 10) |
| |
Fig76a |
Fig.7-6a: Two-site CDE (omega =0.08, f=0, 0.3, 0.7,0.99875) |
| |
Fig76b |
Fig.7-6b: Two-site CDE (omega=0.2, f =0, 0.3, 0.7,0.99875) |
| |
Fig77a |
Fig.7-7a: Two-site CDE for betaR=0.22 - Dirac input |
| |
Fig77b |
Fig.7-7b: Two-site CDE for betaR=0.22 - pulse input |
| |
Fig78 |
Fig.7-8: IVP for the nonequilibrium CDE |
| |
Fig105 |
Equilibrium model, Effect of first-order decay, Step Input |
| |
Fig105a |
Equilibrium model, Effect of first-order decay, Pulse Input |
| |
Fig108 |
One-Site Model, Effect of mass-transfer coefficient |
| |
Fig109 |
Two-site model, Effect of mobile/immobile water ratio, Cf(T) |
| |
Fig109a |
Two-site model, Effect of mobile/immobile water ratio, Cf(Z) |
| |
Fig109b |
Two-site model, Effect of mobile/immobile water ratio, Cr(Z) |
| |
Fig1010 |
Two-site model, Effect of retardation factor, Cf(T) |
| |
Fig1010a |
Two-site model, Effect of retardation factor, Cf(Z) |
| |
Fig1010b |
Two-site model, Effect of retardation factor, Cr(Z) |
| |
Fig1011 |
Two-site model, Effect of mass transfer coefficient, Cf(T) |
| |
Fig1011a |
Two-site model, Effect of mass transfer coefficient, Cf(Z) |
| |
Fig1011b |
Two-site model, Effect of mass transfer coefficient, Cr(Z) |
| |
Fig1012 |
Two-site model, Effect of Peclet number, Cf(T) |
| |
Fig1012a |
Two-site model, Effect of Peclet number, Cf(Z) |
| |
Fig1012b |
Two-site model, Effect of Peclet number, Cr(Z) |
| CXTFIT/Inverse |
Fig73a |
Fig.7-3a: Steady saturated flow in a sand column |
| |
Fig73b |
Fig.7-3b: Steady saturated flow in a sand column |
| |
Fig74 |
Fig.7-4: Estimation of duration time (MASS = 1 in Block B) |
| |
Fig79a |
Fig.7-9a: Tritium effluent curve from Glendale clay loam |
| |
Fig79b |
Fig.7-9b: Boron effluent curve (exp. 3-1, van Genuchten, 1974) |
| |
Fig712 |
Fig.7-12: Field-scale bromide movement (after Jury at al., 1982) |
| |
Fig715 |
Fig.7-15: Hypothetical field-scale reactive solute transport |
| CXTFIT/Stochast |
Fig45a |
Fig4-5: Stream tube model (STM) with random v, BVP vs. (IVP) |
| |
Fig45b |
Fig4-5: Stream tube model (STM) with random v, (BVP) vs. IVP |
| |
Fig47a |
Fig4-7: STM with randomv , Constant and (variable) duration |
| |
Fig47b |
Fig4-7: STM with random v, (Constant) and variable duration |
| |
Fig710 |
Fig.7-10: STM with random v, Effect of sigmav |
| |
Fig711a |
Fig.7-11: STM with random v , ensemble-averaged flux conc. |
| |
Fig711b |
Fig.7-11: STM with random v, field-scale flux conc. |
| |
Fig711c |
Fig.7-11: STM with random v, field-scale resident conc. |
| |
Fig713 |
Fig.7-13: STM with random v and Kd , effect of rhovKd |
| |
Fig714a |
Fig.7-14: Nonequilibrium field-scale transport, field-scale cr |
| |
Fig714b |
Fig.7-14: Nonequilibrium field-scale transport, field-scale ct |
| 3DADE/3DADE |
Example1 |
Figure 2A: Diffuse source in semi-infinite region of surface, Steady-state |
| |
Example2 |
Figure 4: Rectangular source at surface, First-type BC |
| |
Example3 |
Figure 4: Rectangular source at surface, Third-type BC |
| |
Example4 |
Figure 3B: Parallelepipedal initial distribution, Third-type BC |
| |
Example5 |
Figure 7: Circular source at surface, Third-type BC |
| |
Example6 |
Inverse: Diffuse source in semi-infinite region of surface, First-type BC |
| |
Example7 |
Inverse: Parallelepipedal initial distribution, Third-type BC |
| |
Example8 |
Inverse: Parallelepipedal initial distribution, Third-type BC |
| |
Example9 |
Inverse: Circular source at surface, First-type BC |
| N3DADE/N3DADE |
Exampl1a |
BVP: Fig. 6: Instantaneous application from disc (cm,d) |
| |
Exampl1b |
BVP: Fig. 7: Instantaneous application from disc (cm,d) |
| |
Exampl2a |
BVP: Fig. 8: Heaviside application finite rectangle |
| |
Exampl2b |
BVP: Fig. 9: Heaviside application finite rectangle |
| |
Example3 |
IVP: Fig. 10: Heaviside initial, Finite rectangle |
| |
Example4 |
IVP: Fig. 11: Exponential distribution about (5,0,0), Spherical coordinate |
| |
Example5 |
PVP: Fig. 12: Heaviside production, Circular coordinate |
