Monitoring Water Quality Using ArcView GIS Lindsay Chischilly Mentor: Dr. Don Huggins Will Spotts Jeff Anderson Kansas Biological Survey Haskell Indian.

Monitoring Water Quality Using ArcView GIS

Lindsay ChischillyMentor: Dr. Don Huggins

Will Spotts

Jeff AndersonKansas Biological SurveyHaskell Indian Nations University

Overview

Nonpoint Source PollutionWater Quality Research MethodsGeographic Information SystemsResults of Monitoring Program

Definition of Terms

Nonpoint Source Pollution (NPSP)- the broad range of pollution with no specific point of origin. Sources of NPSP include agriculture, industries, and mining. NPSP is weather dependent and not yet subject to federal regulations.

Definition of Terms (continued)

Point Source Pollution-point sources generally enter receiving water bodies at some identifiable site(s) and carry pollutants whose generation is controlled by some internal process or activity, rather than weather.

Clean Water Farms Project

33 farms in eastern Kansas were given federal grant money to address local water quality management issues.

8 farms are monitored by the Kansas Biological Survey.

Purpose of CWFP Monitoring Program

Detect changes in NPSP at the field level.Relate changes in nutrient and herbicide

concentrations to changes in land management.

Participating Farms

Methods

Sampling Devices

Lysimeter

Automatic Runoff SamplerGeographic Information Systems

Methods (continued)

Lysimeters-uses a vacuum and then pressure to collect groundwater at depths of one, four, and eight feet. The eight foot tube are the most reliable samplers.

Methods (continued)

Automatic Runoff Sampler-used to collect eight samples of surface runoff over the first three hours of a storm.

GIS Overview

Computer system capable of holding and using data to describe places on the earth’s surface.

Manipulate, analyze, store, and display spatial data.

Links data to geographic locations

Monitoring Water Quality Using GIS

Monitoring Water Quality Using GIS

Monitoring Water Quality Using GIS

Monitoring Water Quality Using GIS

Monitoring Water Quality Using GIS

Results

1

10

100

1000

0 1 2 3 4 5 6 7 8 9 10 11

Total Phosphorous in Groundwater at Eight FeetThree Locations on Farm 0ne: 1996-2000

Tota

l Phosp

horo

us

(ug/L

)

Sampling Event

Cluster

312

.1

1

10

100

0 1 2 3 4 5 6 7 8 9 10 11

Total Nitrogen in Groundwater at Eight FeetThree Locations on Farm 0ne: 1996-2000

Tota

l Nitr

ogen (

mg/L

)

Sampling Event

Cluster

312

10

100

1000

10000

0 1 2 3 4 5 6 7 8 910111213141516171819

Mean Total Phosphorous in Agricultural Surface RunoffFarm One: 1996-2000

Tota

l Phosp

horo

us

(ug/L

)

Sampling Event

Sampler

1417

.1

1

10

100

0 1 2 3 4 5 6 7 8 910111213141516171819

Mean Total Nitrogen in Agricultural Surface RunoffFarm One: 1996-2000

Tota

l Nitr

ogen (

mg/L

)

Sampling Event

Sampler

1417

Sources of Variation

Seasonal Land Management

Tilling and Planting

Herbicide Application

Compost Spreading

Crop RotationRainfall Event Frequency, Intensity and

Duration

Conclusions

GIS is a creative tool to help visualize and analyze the issues affecting water quality.

There are many contributing factors in the overall water quality in agricultural landscapes.

Groundwater concentrations of TP are more variable than TN over space and time.

Need more time to identify and quantify the specific effects of land management on agricultural water quality.