Samuel A. Miller, Kaycee E. Faunce, Larry B. Barber, Jacob
A. Fleck, Daniel W. Burns, Jeramy R. Jasmann, Michelle L. Hladik, Factors
contributing to pesticide contamination in riverine systems: The role of
wastewater and landscape sources, Science of The Total Environment, Volume
954,2024, 174939, ISSN 0048-9697, https://doi.org/10.1016/j.scitotenv.2024.174939.
The article below is excerpted from the research article
cited above.
The Potomac River Watershed is the second largest watershed
(36,750 km2) within the Chesapeake Bay watershed and
contributes about 15 % of the total streamflow to the Bay.
The mainstem of the Potomac River has minimal flow regulation and is freshwater
and the major source of drinking water for the Washington, D.C. metropolitan area- Loudoun
Water, Fairfax Water, Leesburg Water, WSSC and the Washington Aqueduct.
Population in the Potomac River
Watershed more than doubled from 1970 (3.2 million) to 2020 (6.9 million). The
majority of development during this period occurred in the Washington, D.C.
metropolitan area, where about 84 % of the watershed’s population resided
as of 2020. To accommodate population growth, forest and agricultural lands
have been reduced and public water supply and wastewater treatment systems have
been expanded drawing on the Potomac River itself. A majority of public-supply
withdrawals (80 %) in the Potomac River Watershed are from surface water.
The Potomac River Watershed contains a varied landscape consisting
of steep mountains, rolling hills, broad valleys, and plains. The majority
(53 %) of the basin is forested, 23 % is agricultural, and 13 %
is developed whereas smaller remaining portions contain water, wetlands, and
barren land cover.
According to Miller et al wastewater discharges, although
treated and in compliance with existing regulations, can be a continuous source
of organic contaminants, including pesticides, to the Potomac River and rivers worldwide. Pesticides
can be introduced to wastewater treatment plants by what goes down-the-drain or
flushed down the toilet at homes and businesses. Urban and suburban stormwater enter
the watershed and may include sources of pesticides from residential lawns and
gardens, leaky septic
systems, or outdoor pest control, including applications to impervious surfaces.
Separate sanitary sewer systems can also contain water sourced from groundwater
via infiltration through cracked or broken sewerage pipes.
Frequently, pesticides are transformed or not completely removed
during conventional wastewater treatment which are not designed to address
these contaminants and are discharged in the wastewater treatment plant
effluent to receiving waterbodies. In addition, some wastewater treatment
plants receive industrial discharges. Although pesticides are frequently
introduced to aquatic environments from agricultural and developed land-use
nonpoint sources, wastewater
treatment plant-derived pesticides are of particular concern because they are
continuously discharged to receiving waters that often serve as source
water for drinking water plants. Discharge from the largest wastewater
treatment plant in the study area, UOSA, is one of the largest indirect potable water
reuse sources in the world (Jeffrey et al., 2022).
An integrated model was developed for the Potomac River
watershed to determine the amount of accumulated wastewater percentage of
streamflow and calculate predicted environmental concentrations (PECs) for 14
pesticides in non-tidal National Hydrography Dataset Plus Version 2.1 stream
segments. Model predicted environmental concentrations were compared to
measured environmental concentrations from 32 stream sites that represented a
range of land use to evaluate model performance and to assess possible non-WWTP
loading sources. Statistical agreement between PECs and MECs was moderate- it
was strongest for insecticides, followed by fungicides and herbicides.
Among the target pesticides, PECs generally had the best
agreement with MECs (Fig. 6) for insecticides
(ρ = 0.52, p < 0.01), followed by fungicides
(ρ = 0.36, p < 0.01) and herbicides
(ρ = 0.20, p = 0.14). Individual pesticides
with significant correlations between PECs and MECs included dinotefuran
(ρ = 0.87, p < 0.01), thiabendazole (ρ = 0.82,
p < 0.01), fipronil (ρ = 0.61, p < 0.01),
and tebuconazole (ρ = 0.53, p = 0.02).
Significant correlations were found between these individual pesticide
concentrations and water quality indicators of wastewater presence including
the optical brightener-to-fluorescein ratio, and boron concentrations,
confirming that wastewater treatment plants effluent likely is a source for
these pesticides.
Target pesticide corrected-MECs that had the most
significant correlation with estimated agricultural use included atrazine
(ρ = 0.54, p < 0.01), clothianidin
(ρ = 0.35, p = 0.05), metolachlor
(ρ = 0.62, p < 0.01), and simazine (ρ = 0.70,
p < 0.01). The lack of agreement between corrected-MECs and
estimated pesticide use on agricultural land for the remaining target
pesticides indicates there may be sources beyond wastewater treatment plant effluent
and agriculture during stream base flow conditions.
Pesticides are commonly used within the Potomac River
Watershed for non-agricultural purposes, such as: (1) maintenance of lawns,
gardens, and golf courses, (2) defoliation of rights-of-way, and (3) structural
pest control (Ator et al., 1998). Pesticide
usage rates are not well documented for these categories, which makes source
identification difficult.
The U.S. Environmental Protection Agency estimated in 2012
that more money was spent on insecticides used in home and gardens
($2,650,000,000) than in agriculture ($1,499,000,000) and industry
($700,000,000) combined, and overall, 27 million kilograms of pesticides were
applied to home and garden areas (Atwood and Paisley-Jones, 2017).
Homeowners frequently apply high rates of pesticides beyond the recommended
doses that unintentionally leave residues that pose a variety of human and
ecological health threats (Md Meftaul et al., 2020).
Water-quality samples were collected from 32 streams within
the Potomac River Watershed during low-flow conditions to represent periods
with the greatest effects from ACCWW and legacy pesticide sources. In the study
watersheds, turfgrass percentage of
drainage area was found to be significantly correlated with all target
fungicides, insecticides, and diuron. This study did not assess variability in
results over time, which may be important at some sites based on local
conditions. At best this model could be used as a screening tool and not
much more.
