Title: Final Review
1Final Review
- Exam cumulative incorporate complete midterm
review
2Calculus Review
3Derivative of a polynomial
- In differential Calculus, we consider the slopes
of curves rather than straight lines - For polynomial y axn bxp cxq ,
derivative with respect to x is - dy/dx a n x(n-1) b p x(p-1) c q x(q-1)
4Example
y axn bxp cxq
dy/dx a n x(n-1) b p x(p-1) c q x(q-1)
5Numerical Derivatives
- finite difference approximation
- slope between points
- dy/dx Dy/Dx
6Derivative of Sine and Cosine
- sin(0) 0
- period of both sine and cosine is 2p
- d(sin(x))/dx cos(x)
- d(cos(x))/dx -sin(x)
7Partial Derivatives
- Functions of more than one variable
- Example h(x,y) x4 y3 xy
8Partial Derivatives
- Partial derivative of h with respect to x at a y
location y0 - Notation ?h/?xyy0
- Treat ys as constants
- If these constants stand alone, they drop out of
the result - If they are in multiplicative terms involving x,
they are retained as constants
9Partial Derivatives
- Example
- h(x,y) x4 y3 x2y xy
- ?h/?x 4x3 2xy y
- ?h/?xyy0 4x3 2xy0 y0
10WHY?
11Gradients
- del h (or grad h)
- Darcys Law
12Equipotentials/Velocity Vectors
13Capture Zones
14Watersheds
http//www.bsatroop257.org/Documents/Summer20Camp
/Topographic20map20of20Bartle.jpg
15Watersheds
http//www.bsatroop257.org/Documents/Summer20Camp
/Topographic20map20of20Bartle.jpg
16Capture Zones
17Water (Mass) Balance
- In Out Change in Storage
- Totally general
- Usually for a particular time interval
- Many ways to break up components
- Different reservoirs can be considered
18Water (Mass) Balance
- Principal components
- Precipitation
- Evaporation
- Transpiration
- Runoff
- P E T Ro Change in Storage
- Units?
19Ground Water (Mass) Balance
- Principal components
- Recharge
- Inflow
- Transpiration
- Outflow
- R Qin T Qout Change in Storage
20Ground Water Basics
- Porosity
- Head
- Hydraulic Conductivity
21Porosity Basics
- Porosity n (or f)
- Volume of pores is also the total volume the
solids volume
22Porosity Basics
- Can re-write that as
- Then incorporate
- Solid density rs
- Msolids/Vsolids
- Bulk density rb
- Msolids/Vtotal
- rb/rs Vsolids/Vtotal
23Ground Water Flow
- Pressure and pressure head
- Elevation head
- Total head
- Head gradient
- Discharge
- Darcys Law (hydraulic conductivity)
- Kozeny-Carman Equation
24Pressure
- Pressure is force per unit area
- Newton F ma
- F force (Newtons N or kg ms-2)
- m mass (kg)
- a acceleration (ms-2)
- P F/Area (Nm-2 or kg ms-2m-2
- kg s-2m-1 Pa)
25Pressure and Pressure Head
- Pressure relative to atmospheric, so P 0 at
water table - P rghp
- r density
- g gravity
- hp depth
26P 0 ( Patm)
Pressure Head
Pressure Head (increases with depth below surface)
Elevation
Head
27Elevation Head
- Water wants to fall
- Potential energy
28Elevation Head (increases with height above datum)
Elevation
Elevation Head
Elevation datum
Head
29Total Head
- For our purposes
- Total head Pressure head Elevation head
- Water flows down a total head gradient
30P 0 ( Patm)
Pressure Head
Total Head (constant hydrostatic equilibrium)
Elevation
Elevation Head
Elevation datum
Head
31Head Gradient
- Change in head divided by distance in porous
medium over which head change occurs - A slope
- dh/dx unitless
32Discharge
- Q (volume per time L3T-1)
- q (volume per time per area L3T-1L-2 LT-1)
33Darcys Law
- q -K dh/dx
- Darcy velocity
- Q K dh/dx A
- where K is the hydraulic conductivity and A is
the cross-sectional flow area - Transmissivity T Kb
- b aquifer thickness
- Q T dh/dx L
- L width of flow field
1803 - 1858
www.ngwa.org/ ngwef/darcy.html
34Mean Pore Water Velocity
- Darcy velocity
- q -K ?h/?x
- Mean pore water velocity
- v q/ne
35Intrinsic Permeability
L2
L T-1
36More on gradients
37More on gradients
h
412 m
h
400 m
100 m
h
38More on gradients
h 10m
- Three point problems
- (2 equal heads)
412 m
h 10m
400 m
CD
- Gradient (10m-9m)/CD
- CD?
- Scale from map
- Compute
100 m
h 9m
39More on gradients
h 11m
- Three point problems
- (3 unequal heads)
Best guess for h 10m
412 m
h 10m
400 m
- Gradient (10m-9m)/CD
- CD?
- Scale from map
- Compute
CD
100 m
h 9m
40Types of Porous Media
Isotropic
Anisotropic
Heterogeneous
Homogeneous
41Hydraulic Conductivity Values
K (m/d)
8.6
0.86
Freeze and Cherry, 1979
42Layered media (horizontal conductivity)
Q4
Q3
Q2
Q1
Q Q1 Q2 Q3 Q4
K2
b2
K1
b1
Flow
43Layered media(vertical conductivity)
R4
Q4
Flow
R3
Q3
K2
b2
R2
K1
b1
Q2
Controls flow
R1
Q1
Q Q1 Q2 Q3 Q4
The overall resistance is controlled by the
largest resistance
The hydraulic resistance is b/K
R R1 R2 R3 R4
44Aquifers
- Lithologic unit or collection of units capable of
yielding water to wells - Confined aquifer bounded by confining beds
- Unconfined or water table aquifer bounded by
water table - Perched aquifers
45Transmissivity
46Schematic
b2 (or h2)
T2 (or K2)
i 2
d2
k2
b1
T1
i 1
d1
k1
47Pumped Aquifer Heads
b2 (or h2)
i 2
d2
b1
i 1
d1
48Heads
h2 - h1
b2 (or h2)
h2
i 2
d2
h1
b1
i 1
d1
49Flows
h2
h2 - h1
b2 (or h2)
h1
i 2
d2
qv
b1
i 1
d1
50Terminology
- Derive governing equation
- Mass balance, pass to differential equation
- Take derivative
- dx2/dx 2x
- PDE Partial Differential Equation
- CDE or ADE Convection or Advection Diffusion or
Dispersion Equation - Analytical solution
- exact mathematical solution, usually from
integration - Numerical solution
- Derivatives are approximated by finite differences
51Derivation of 1-D Laplace Equation
- Inflows - Outflows 0
- (qxx- qxxDx)DyDz 0
Governing Equation
52Boundary Conditions
- Constant head h constant
- Constant flux dh/dx constant
- If dh/dx 0 then no flow
- Otherwise constant flow
53General Analytical Solution of 1-D Laplace
Equation
54Particular Analytical Solution of 1-D Laplace
Equation (BVP)
BCs - Derivative (constant flux) e.g., dh/dx0
0.01 - Constant head e.g., h100 10 m
After 1st integration of Laplace Equation we have
After 2nd integration of Laplace Equation we have
Incorporate derivative, gives A.
Incorporate constant head, gives B.
55Finite Difference Solution of 1-D Laplace Equation
Need finite difference approximation for 2nd
order derivative. Start with 1st order.
Look the other direction and estimate at x Dx/2
56Finite Difference Solution of 1-D Laplace
Equation (ctd)
Combine 1st order derivative approximations to
get 2nd order derivative approximation.
Solve for h
572-D Finite Difference Approximation
58Poisson Equation
- Add/remove water from system so that inflow and
outflow are different - R can be recharge, ET, well pumping, etc.
- R can be a function of space
- Units of R L T-1
59Derivation of Poisson Equation
(qxx- qxxDx)Dyb RDxDy 0
60General Analytical Solution of 1-D Poisson
Equation
61Water balance
- Qin RDxDy Qout 0
- qin bDy RDxDy qout bDy 0
- -K dh/dxin bDy RDxDy -K dh/dxout bDy 0
- -T dh/dxin Dy RDxDy -T dh/dxout Dy 0
- -T dh/dxin RDx T dh/dxout 0
62Dupuit Assumption
- Flow is horizontal
- Gradient slope of water table
- Equipotentials are vertical
63Dupuit Assumption
(qxx hxx - qxxDx hxDx)Dy RDxDy 0
64Transient Problems
- Transient GW flow
- Diffusion
- Convection-Dispersion Equation
- All transient problems require specifying initial
conditions (in addition to boundary conditions)
65Storage Coefficient/Storativity
- S is storage coefficient or storativity The
amount of water stored or released per unit area
of aquifer given unit head change - Typical values of S (dimensionless) are 10-5
10-3 - Measuring storativity derived from observations
of multi-well tests - GEOS 4310/5310 Lecture Notes, Fall 2002Dr. T.
Brikowski, UTD
http//www.utdallas.edu/brikowi/Teaching/Geohydro
logy/LectureNotes/Regional_Flow/Storativity.html
661-D Transient GW Flow
671-D Transient GW Flow Deriving the Governing PDE
qxxDx
qxx
(qxxDx - qxx)Dyb -SDxDy?h/?t
68(No Transcript)
69Finite Difference Solution
- First order spatial derivative
70Second order spatial derivative
71Finite Difference Solution
hx, t-Dt
72All together
73- Stability criterion TDt/(SDx2) lt ½.
74Diffusion
75 76Temporal Derivative
Cx, t-Dt
77All together
78Boundary conditions
- Specify either
- Concentrations at the boundaries, or
- Chemical flux at the boundaries (usually zero)
- Fixed concentration boundary concept is simple.
- Chemical flux boundary is slightly more
difficult. We go back to Ficks law -
- Notice that if ?C/?x 0, then there is no flux.
The finite difference expression we developed for
?C/?x is - Setting this to 0 is equivalent to
79Convection-Dispersion Equation
- Key difference from diffusion here!
- Convective flux
80CDE
81Finite Difference Spatial
82Finite Difference Temporal
83Centered Finite Difference
- For first order spatial derivative
- Worked for estimating second order derivative
(estimate ended up at x). - Need centered derivative approximation
84All together
- prone to numerical instabilities depending on the
values of the factors DDt/Dx2 and vDt/2Dx
85Boundary conditions
- Specify either
- Concentrations at the boundaries, or
- Chemical flux at the boundaries
- Fixed concentration boundary concept is simple
- Chemical flux boundary is slightly more
difficult. We go back to the flux - Notice that if ?C/?x 0, then there is no
dispersive flux but there can still be a
convective flux. This would apply at the end of a
soil column for example the water carrying the
chemical still flows out of the column but there
is no more dispersion. One of the finite
difference expressions we developed for ?C/?x is - Setting this to 0 is equivalent to
86Fitting the CDE
87Adsorption Isotherm
88Koc Values
89Organic Carbon Partitioning Coefficients for
Nonionizable Organic Compounds. Adapted from
USEPA, Soil Screening Guidance Technical
Background Document. http//www.epa.gov/superfund/
resources/soil/introtbd.htm
90Retardation
- Incorporate adsorbed solute mass
91Sample problem
- A tanker truck collision has resulted in a spill
of 5000 L of the insecticide diazinon 2000 m from
the City of Miamis water supply wells. Use a
rule of thumb to estimate the dispersivity for
the plume that is carrying the contaminant from
the spill site to the wells.
92Sample problem
- The transmissivity determined from aquifer tests
is 100,000 m2 d-1 and the aquifer thickness is 20
m. The head in wells 1000 m apart along the flow
path is 3.1 and 3 m. What is the gradient? What
is the mean pore water velocity and what is the
dispersion coefficient?
93Sample problem
- You look up the Koc value of diazinon (290 ml/g).
The aquifer material you tested has an foc of
0.0001. What is the Kd? If the porosity is 50
and the bulk density is 1.5 Kg L-1, what is R? - Assume retarded piston flow and estimate the
arrival time of the insecticide at the well field
using the appropriate data from the preceding
problems.
94Retardation
95Aquifer Tests
Matching aquifer test data to the Theis type
curve has resulted in the match point coordinates
1/u 10, W(u) 1, t 83.9 minutes, and s
0.217 m. The pumping rate is 1 m3 min-1 and the
observation well is 100 m away from the pumping
well. Compute the aquifer transmissivity and
storativity. Be sure to specify the
units. Hints T Q/(4ps) W(u) S 4Ttu/r2.
96Ghyben-Herzberg
h
z
z
Pf Ps rg(hz) rsgz r(hz) rsz rh (rs-r)
z? h r/(rs-r) z
97Ghyben-Herzberg
- Seawater 1.025 g cm-3
- h r/(rs-r) z
- h 1/(1.025 - 1) z
- h 40 z
98Major Cations and Anions
- Cations
- Ca2, Mg2, Na, K
- Anions
- Cl-, SO42-, HCO3-
99Chemical Concentration Conversions
- Usually given ML-3 (e.g. mg L-1 mg L-1)
- Convert to mol L-1
100Charge Balance
101Piper Diagrams
102Stiff Diagrams
http//water.usgs.gov/pubs/wri/wri024045/htms/repo
rt2.htm
103Redox Reactions
- O2 (disappear)
- NO3- (disappear)
- Fe/Mn (appear in solution)
- SO42- (disappear)
- CH4 (appear)