Post on 22-Jan-2016
Overview and Issues of the High Overview and Issues of the High Plains Aquifer, Oklahoma, 2010Plains Aquifer, Oklahoma, 2010
Mark F. Becker
U.S. Geological SurveyOklahoma City, Oklahoma
Outline of PresentationOutline of Presentation
Issues (addressed throughout presentation) Location and Setting Oklahoma Water Law Hydrology and Water-Quality
Water-Uses and Effects of Withdrawal Future of Irrigated Agriculture
Conclusions
Issues
1. Long way from State Capitol
2. Sparsely Populated (Small Legislative Representation)
3. Oklahoma Water Law
4. Groundwater Level Declines
5. Future for Irrigation
Issue #1: The Central High Plains and Oklahoma
Kansas
Oklahoma
Texas
New Mexico
Colorado
Issue # 2: Sparse Population
Estimated Population of Panhandle in 2009 was 30,035
Setting
Overlies approximately 7,100 mi2 in OklahomaTexas County is Largest Ag Producer in OKMean annual precipitation around 19-in/yrTemperature range: -25o F to +110o FAverage lake evaporation = 62-in/yearAverage runoff (pre-1970) = 0.2-in/year
Land Use (Oklahoma Portion)
56% rangeland
40% dry cropland
4% irrigated cropland
Harvested Acres (Oklahoma Portion)
Wheat 2,600,000 acres
Corn 800,000
Sorghum 700,000
Hay 300,000
Other 65,000
Livestock (Oklahoma High Plains)
620,000 cattle in 1992 750,000 cattle in 1997
20,000 swine in 1992 > 2,700,000 in 1999
Issue #3: Oklahoma Water Law
Oklahoma has a “mining” based regulatory approach to groundwaterProperty RightAllows for depletion over timeAllocations are for high capacity wells and until
determined set at 2 acre-ft/ac/yr for land ownedDoes not recognize hydraulic connection to surface waterNo effective monitoring
Kansas has highly regulated sustainable based lawTexas has essentially no jurisdiction over groundwater
Hydrogeology
Series of coalescing alluvial fans consisting of sand, clay, and gravel that can exceed 500’ in thickness
Well yields can exceed 2,000 GPMDirection of groundwater flow is from west to eastRecharge is distributedRecharge is relatively rapidWater-level declines from irrigation withdrawals
Center-pivot Irrigation began in the early 1960’s in Oklahoma
Center Pivot Technology Changed Center Pivot Technology Changed Irrigation Practices Irrigation Practices
Land with rolling topography could be irrigated
Circles are 0.5 mile in diameter
Each well pumps about 1,500 gpm
Percent Ground-Water Use in the Central High Plains in 1992
Per
cen
t W
ater
Use
Water Use in 2005
252Mgal/d
Groundwater Flow
Saturated Thickness (1998)
>300
100-300
<50
50-100
Issue #4: Water-Level Declines
Long-term effects on streamflow EcosystemsTreated municipal wastewater
Increased pumping costsPotentially reduces irrigated agricultural opportunitiesCreates acrimony (whiskey’s for drinking, water’s for
fighting)
Water-Level Changes to 1980
Declines more than 100 Declines more than 100 feet in Kansas, Oklahoma, feet in Kansas, Oklahoma,
and Texasand Texas
Declines of 10-50 feet Declines of 10-50 feet widespreadwidespread
Rises more than 25 feet in Rises more than 25 feet in NebraskaNebraska
Large areas of little on no Large areas of little on no changechange
Water-Level Changes to 1997
Areas of declines have Areas of declines have expandedexpanded
Areas of rises have Areas of rises have expanded, especially in expanded, especially in
Texas and OklahomaTexas and Oklahoma
Large rises in Nebraska Large rises in Nebraska continuecontinue
Water-Level Change from Predevelopment to 1998
10-25
± 10
Rise
>50 25-50
Near Guymon 07232500
Stream Gaging Station
Ground Water Well
Optima Lake
Canton Lake
At Beaver 07234000
At Woodward07237500
Near Seiling07238000
Well
A Lesson in Planning: The Beaver/North Canadian River Basin
Upstream face of Optima Dam in 1990
Aerial Photo by Dale Boyle, U.S. Geological Survey
Increases in Numbers of Large-Capacity Irrigation Wells in the Oklahoma Panhandle
1930 1940 1950 1960 1970 1980 1990 2000
YEAR
0
500
1000
1500
2000
2500
NU
MB
ER
OF
WE
LL
S
Depth to Water in a key Oklahoma Well in the High Plains Aquifer
Percentage of no-flow days for theBeaver River near Guymon, Okla.
1930 1940 1950 1960 1970 1980 1990 2000YEAR
0
20
40
60
80
100
PE
RC
EN
T O
F D
AY
S W
ITH
NO
FL
OW
Annual Precipitation (bars) and 10-year moving average (line) for western Oklahoma
Annual flow volume (bars) and 10-year moving average (line) near Guymon (07232500)
Annual Peak Discharge (bars) and 10-year moving average (line) near Guymon, OK (07232500)
Recharge
Myth #1: Recharge comes from snowmelt in the Rockies
Myth#2: Aquifer receives little or no rechargeReality: Distributed recharge from precipitation
Estimated Depth to Water in Feet
Tri
tiu
m
Un
its
18O/16OVSMOW ‰
Deu
teriu
mV
SM
OW ‰
Predevelopment Recharge
4.0% of precipitation in sand-dune areas. Averaged 0.69 inches per year. 139,000 acre-feet per year. 14% of model area.
0.37% of precipitation in other areas. Averaged 0.07 inches per year. 85,000 acre-feet per year. 86% of model area.
Cultivated Dryland Recharge
Extra recharge due to dryland cultivation
3.9% of precipitation over area in dryland; about 0.65 inches per year
345,000 acre-feet per year
Dryland Recharge
30
40
50
1940 1990
De
pth
to
Wa
ter
Constituent Minimum Maximum Mean Median
Temperature oC 14.3 17.4 16.2 16.5 Specific Conductance
470 782 600 595
Dissolved Oxygen * 5.2 7.9 7.6 7.7 pH 7.3 7.9 7.6 7.7 NO2 + NO3 as N* 1.81 12.3 5.30 3.43 Calcium* 27 110 62 60 Magnesium* 4.5 51 26 27 Sodium* 8.9 46 29.4 31.5 Potassium* 0.76 6.2 4.03 4.35 Chloride* 2.1 66 33.3 30.0 Sulfate* 10 180 56 42 Alkalinity* as CaCO3 171 273 207 195
* mg/L
Summary Statistics for Common Ions and Field Parameters
Issue # 5: Future of IrrigationIssue # 5: Future of Irrigation
Tied to prices of fuel and crops New technologies allow exploitation of
lower well yieldsGenetically modified cropsLow/No Till methodsEconomy of scale; larger farms, less
farmers
Conclusion
Politically, not well represented but recognized by the economic value.
Contrasting water management strategies on bordersDeclines in water levels
Increased costsLoss of surface water
Potential for technological advances to keep irrigated agriculture a component
The End
OWRB Sites
ConclusionsConclusions
NO3 is elevated in most wells
NO3 is found at all well depths15N indicates the presence of animal wastesChanges ahead as more data is evaluated
NO
2 +
NO
3 m
g/L
as N
Estimated Depth to Water in Feet
OWRB Data
15N
Air ‰
NO2 + NO3 mg/L as N
Fertilizer
Mixed Animal, Fertilizer, or Soil
Animal
Types of Water-Quality Data (OWRB)
Field measurements (temperature, pH, alkalinity, O2, specific conductance)
Chemical analyses (common ions, metals, nutrients, 15N, 18O, and deuterium)
Age dating (tritium, tritium/helium, and 14C)
Location of Central High Plains NAWQA Study Area
New Mexico
Colorado
Kansas
Oklahoma
Texas
Sub Unit Survey
Reconnaissance
Public Supply
NO2 + NO3 mg/L as N
Trit
ium
Water-quality Data Collected in 1999
Oklahoma water resources board (OWRB)- 12 Wells
NAWQA Sub Unit Surveys- 94 wellsNAWQA Regional Transect - 5 well clusters
(15 Wells)NAWQA reconnaissance - 5 wellsNAWQA Public Supply Survey- 15 wells
Outline of PresentationOutline of Presentation
Describe Oklahoma setting and similarities to the entire Central High Plains
Describe Oklahoma High Plains study and High Plains NAWQA
Water-quality in Oklahoma High PlainsConclusions
15 N
Air ‰
Estimated Depth to Water in Feet
Fertilizer
Mixed Animal, Fertilizer, or Soil
Animal