A 1–ha field with Pine Flat loamy sand (coarse–loamy, siliceous, thermic Typic Paleudult) and Troup loamy sand
(loamy, siliceous, thermic Grossarenic Kandiudult) surface soils, located near Plains, Georgia, was studied for four years
(1993 to 1996) to evaluate potential agrichemical transport to groundwater. The field was managed to produce summer corn
and winter wheat. Commercial fertilizer, the herbicide atrazine, and the insecticide carbofuran were applied to the field in
1993, 1994, and 1995. Average annual application rates were 266 kg nitrogen ha–1, 2.5 kg atrazine ha–1, and 2.4 kg
carbofuran ha–1. Monthly soil–water and groundwater samples were collected. The samples were analyzed for nitrate
nitrogen (NO3
––N), chloride, atrazine, carbofuran, and deethylatrazine (DEA). Soil–water and groundwater samples
indicated elevated NO3
––N concentrations (>5 ppm) in the vadose zone at 4.3 m and in the aquifer at 10 m (>4 ppm). Of the
studied pesticides, carbofuran and DEA were observed at the greatest concentrations in groundwater.
Both NO3
––N and pesticides were transported during groundwater recharge following periods of excess precipitation.
Peak pesticide concentrations in groundwater were observed in late 1994, driven by a large precipitation event in July of 1994
when 565 mm of rain fell over a 4–day period. Atrazine and carbofuran concentrations in groundwater did not exceed the
EPA maximum contaminant levels of 3 ppb and 40 ppb, respectively. Spatially averaged concentrations observed in monthly
groundwater collected directly below the field were well below these standards. Concentrations of NO3
––N, atrazine, DEA,
and carbofuran observed in groundwater from the on–field wells were significantly different from up–gradient and
down–gradient concentrations (p = 0.05). These data indicate a significant impact to the local groundwater. Nitrate N was
transported down–gradient from the field at the largest concentrations. Peak concentrations of atrazine and DEA were
simultaneously observed in the groundwater, indicating similar transport rates for both compounds and rapid transformation
from atrazine into DEA in the root–zone.
[1]
J. Gaynor,et al.
Atrazine and Metolachlor Loss in Surface and Subsurface Runoff from Three Tillage Treatments in Corn
,
1995
.
[2]
W. Battaglin,et al.
Herbicides and their metabolites in rainfall: Origin, transport, and deposition patterns across the midwestern and northeastern United States, 1990-1991
,
1997
.
[3]
L. E. Asmussen,et al.
Relationship of Geology, Physiography, Agricultural Land Use, and Ground‐Water Quality in Southwest Georgiaa
,
1985
.
[4]
R. A. Leonard,et al.
Herbicide Runoff from Upland Piedmont Watersheds—Data and Implications for Modeling Pesticide Transport
,
1979
.
[5]
E. Thurman,et al.
Formation and transport of deethylatrazine in the soil and vadose zone
,
1991
.
[6]
David D. Bosch,et al.
Preferential Flow and Pedotransfer Functions for Transport Properties in Sandy Kandiudults
,
2000
.
[7]
M. Kamrin.
Pesticide Profiles: Toxicity, Environmental Impact, and Fate
,
1997
.
[8]
R. A. Leonard,et al.
EFFECTS OF PESTICIDE, SOIL, AND RAINFALL CHARACTERISTICS ON POTENTIAL PESTICIDE LOSS BY PERCOLATION-A GLEAMS SIMULATION
,
1991
.
[9]
Ralph A. Leonard,et al.
ATRAZINE AND CARBOFURAN TRANSPORT THROUGH THE VADOSE ZONE IN THE CLAIBORNE AQUIFER RECHARGE AREA
,
2000
.
[10]
B. Lowery,et al.
Irrigation and Tillage Effects on Atrazine and Metabolite Leaching from a Sandy Soil
,
1996
.
[11]
K. Jayachandran,et al.
Occurrence of Atrazine and Degradates as Contaminants of Subsurface Drainage and Shallow Groundwater
,
1994
.
[12]
R. Clark,et al.
Drinking water from agriculturally contaminated groundwater
,
1991
.
[13]
Ralph A. Leonard,et al.
TRACER STUDIES OF SUBSURFACE FLOW PATTERNS IN A SANDY LOAM PROFILE
,
1999
.
[14]
Robert K. Hubbard,et al.
Nitrate movement to groundwater in the southeastern coastal plain
,
1989
.
[15]
D. Bosch,et al.
Hydraulic conductivity variability for two sandy soils
,
1998
.
[16]
Adel Shirmohammadi,et al.
Pesticide Transport in Shallow Groundwater
,
1988
.