The study area is a small watershed (area ∼ 0.45 km²) with a pond within a larger, fenced pasture, located on a privately owned crop-livestock integrated farm in the southern Coastal Plain of Georgia, USA (Fig. 1a). The farm is referred to as the Sumner Cooperator Farm (SCF). Currently, the area is used for cow grazing. The climate is humid subtropical, with a mean annual temperature of 18.8 °C and mean annual precipitation of 1174 mm.

The land surface's Digital Elevation Model of 1 m resolution was downloaded from the Open Topography portal (https://opentopography.org/, last access: 5 May 2026). The altitude of the land surface varies from 101.8 to 119.7 m (Fig. 1b).

Soil cover at the site consists of a loamy sand (average of 85 % sand, 9 % silt, and 7 % clay) to depths of 60–80 cm, underlain by sandy clay loam (average of 62 % sand, 8 % silt, and 30 % clay) containing plinthite, a low permeability layer of hard iron-rich soil restricting hydraulic connectivity between surface and groundwater (Blume et al., 1987). The latter soil was used to build the bottom of the pond and the dam.

Weather conditions were monitored by the USDA-ARS Southeast Watershed Research Laboratory (SEWRL) at the site to measure air temperature and humidity, wind speed, solar radiation, and soil and water temperature. Data were collected from a climate station located at the SCF noted as “Rain Gage 80” in the SEWRL public data website (https://radio.tiftonars.org/rg80.htm, last access: 5 May 2026). Specifications for instrumentation follow the configurations for the Little River Experimental Watershed climate stations described in Bosch et al. (2007).

Cattle use of the pond and the pasture area draining into the pond was evaluated using automated trail cameras. Eight cameras were fixed to solid structures (e.g., fence posts, trees) and their fields of view (FOVs) captured overlapping images of the pond at regular intervals. Three comparable camera models were used for the study, including 3 Bushnell 24MP Prime Low Glow (Model 119932C), 3 CamPark, and 2 Coleman (Model CHD400W) cameras. Cattle in the pond were imaged from July 2022 to December 2023. Secure digital (SD) removable media cards were used to record the imagery and were replaced every 6 to 10 weeks for the duration of the study. Imagery was downloaded and stored on a file server for subsequent analysis. The imagery was visually assessed for pond use by cattle by a single observer for all days. Images were reviewed from each camera, and the number of cows in the pond was counted in each image. Tallied viewpoint counts were summed according to the model finite element mesh (FEM) nodes segmentation of the shoreline described below, multiplied by the time interval of the camera setting (5 to 30 min), and divided by 1440 min d⁻¹. The resulting values were summed for each shoreline segment to produce a daily value of “cow days” (Cex). To evaluate the accuracy of the visual assessment, two additional independent observers conducted validation counts of a sample of the imagery following the same protocol, and agreement among the three observers (OBS1, OBS2, and OBS3) was evaluated.

Between February and May 2023, 18 fresh cow manure samples were collected from the area around the pond. Samples were collected into 50 mL conical tubes using a sterilized tongue depressor and were then placed on ice for storage and transport to the laboratory. Laboratory processing of manure samples occurred within 24 h of sample collection. Briefly, 2 g of manure was blended with 200 mL of sterile, deionized water for 2 min on the highest setting. Mixed samples were then allowed to settle for 15 min before aliquots were used to prepare serial dilutions of the manure mixture. Diluted manure solutions were processed in duplicate using the Colilert method (IDEXX, Westbrook, Maine), which produced a most-probable-number (MPN) of E. coli in each sample. An MPN was then calculated per mass of manure (MPN E. coli kg⁻¹) using information from a dry weight analysis of the manure.

Figure 2 shows the locations of the water sampling points for measurements of E. coli concentration and of the camera viewpoints for monitoring cattle. For the water sampling points, locations with even numbers (2, 4, 6, 8, 10, 12, 14, 16, not shown) have coordinates the same as locations with odd numbers (1, 3, 5, 7, 9, 11, 13, and 15), respectively. However, locations with odd numbers were sampled at the pond surface, whereas locations with even numbers were sampled at a depth of 50 cm using a peristaltic pump. Locations 17 to 26 were sampled at the surface near the banks. All samples were taken between 10:00 and 12:00 EST in the absence of cows.

Accounting for the complexity of hydrogeological and hydrochemical processes, we choose the HGS (Therrien et al., 2010) as a basis for the model. In HGS, the flow of water is simulated in a fully integrated mode; water derived from rainfall inputs is partitioned into components such as overland and stream flow, evaporation, infiltration, recharge, and subsurface discharge into surface water features such as lakes, streams, and wetlands in a natural, physics-based fashion. It employs a fully coupled numerical approach, allowing the simultaneous solution of both the surface and variably saturated subsurface flow, solute transport, and heat transfer.

The mathematical model of the watershed flow and transport comprises the following components. The Richards equation simulates three-dimensional transient subsurface flow in a variably saturated porous medium (PM domain). The van Genuchten (1980) relations are used to calculate the pressure-saturation relationship and hydraulic conductivity. The two-dimensional depth-averaged diffusive wave equation describes overland water flow (OVL domain). The subsurface and surface flow equations are fully coupled. Evapotranspiration affects surface and subsurface flow domains and is modeled as a combination of transpiration from vegetation and evaporation. Microbial transport is described by 3D and 2D coupled advection-dispersion equations in the subsurface and surface, respectively. We chose the linear Henry isotherm for simulating E. coli sorption. A first-order decay reaction describes the bacteria's die-off. The present model does not explicitly simulate soil and manure erosion, suspended sediment transport, settling, or resuspension. As a result, bacterial transport is represented primarily through direct runoff and overland flow pathways, without accounting for attachment to or release from suspended or bed sediments. However, the model accounts for the release of bacteria from cowpats uploaded onto the soil surface.

The numerical solution of partial differential equations and the initial and boundary conditions are done by the control volume finite element approach.

We adopted the values of model parameters from different sources or estimated based on existing experimental data or during simulations. Tables 1 and 2 present parameter values used in the simulations.

The geology of the subsurface is not well known. The following composition of soil layers was accepted, based on available information: loamy sand to a depth of 0.5 m, below which a clay layer of variable thickness extends down to the upper half of layer U1 (Fig. 3b). The lower half of U1 is presented by sandy clay loam. The pond bottom (to 0.5 m depth) and the dam are built from clay with the hydraulic conductivity of 0.0002 m d⁻¹.

E. coli fate and transport simulations were performed for 2022–2023. To progress the numerical convergence and reduce simulation time, we use relative concentrations Cr=C/Cmax, where Cmax=1.4⋅1010 MPN m⁻³ is the maximum value of boundary concentration at the soil surface. The value of the longitudinal dispersivity values for the porous media domain was chosen to be 10 m, considering the scale problem (Neuman, 1990). There is no data concerning longitudinal dispersivity for the overland flow domain. Therefore, we tested a few values of this parameter from 5 to 15 m. Longitudinal dispersivity equal to 12.5 m produced a better agreement between simulated and observed concentrations. The transverse dispersivities were 1/5 of the longitudinal ones for porous media and overland flow domains.

E. coli die-off/inactivation rates exhibit considerable variability depending on environmental conditions, e.g., temperature, moisture, pH, organic matter content, attachment to particles, solar radiation, predation, and matrix type such as manure, soil, runoff, or pond water (Lim and Flint, 1989; Soupir, 2007; Ravva and Korn, 2007; Muirhead and Littlejohn, 2009; Oliver et al., 2006; Tran et al., 2020). The E. coli die-off parameters in Tables 1 and 2 were taken as average over the parameters for datasets presented in published databases. The Q10 model parameters of E. coli survival in water were averages over 16 survivals in wastewater datasets presented in the work of Blaustein et al. (2013), and the Q10 model parameters of E. coli survival in manure were averages over seven experimental datasets with bovine manure published by Martinez et al. (2013).The E. coli temperature-dependent die-off in manure, soil, and water was simulated. The current version of HGS does not allow the die-off rate in the surface flow domain to be prescribed as a function of temperature. Therefore, this parameter (Tables 1 and 2) was recalculated for each three-month-long season using mean temperature values and used piecewise by restarting simulations for each time interval.

All simulations were carried out using available weather data for a time interval from 1 January 2021, to 31 December 2023. Annual precipitation was 1375, 998, and 1167 mm in 2021, 2022, and 2023, respectively. Figure 4 shows rainfall and calculated potential evapotranspiration in the study area in 2021–2023.

The surface Cauchy-type boundary concentration at the grazing area (Fig. 3a) was calculated using the equations presented in Appendix A, as described above in Sect. 2.3.3. We assume that 50 cattle (the maximum number of animals that appeared in monitoring camera photos) were grazing in the watershed. The total grassland area of around 60 000 m² was estimated based on recent aerial imagery provided in Google Earth (version Pro 7.3). Nennich et al. (2005) estimated the average daily load of manure of 38.6 and 66.3 kg d⁻¹ per cow for dry and lactating cows, respectively. The ratio of urine to feces in dairy cows varies, but on average, slightly less than one-third of manure is urine. Thus, we estimate average daily feces excretion as 0.5×(38.6+66.3)×0.667=35 kg d⁻¹ per cow. Monitoring shows that during the day, cows usually graze for at least 12 h. Therefore, we estimate solid manure load M0= kg d⁻¹ per cow × 12 h/24 h × 50 cows/60 000 m² = 0.0146 kg m⁻². The initial concentration of E. coli in fresh cowpats, mi0=7.38⋅108 MPN kg⁻¹, was calculated as an average in 16 samples collected in 2023. Other parameters in Eqs. (A3)–(A4) were αm=23.375 h⁻¹, βm=1.732, and Er=1 (Stocker et al., 2018). No cattle were observed in the field from the beginning of December to the end of February. Figure 5 shows the calculated boundary concentrations.

The influx of source terms representing E. coli loading from direct cattle excretion into the pond was calculated as described in Sect. 2.4.3. Validation of the visual assessment of trail camera imagery to derive Cex yielded strong correlations among the three independent observers (OBS1 v OBS2, n=64, R2=0.93; OBS1 v OBS3, n=46, R2=0.90; OBS2 v OBS3, n=18, R2=0.99). It was assumed that all bacteria were immediately released from manure in the pond. Accounting for the daily cow excretion (as explained above for the surface boundary concentration) and E. coli concentration in cowpats, we calculated the daily source rate for each pond zone (Fig. 6) as a portion of the daily manure excretion. The rate for each node is one-tenth of the zone rate. Cattle use monitoring started in July 2022. Therefore, in simulations for the period January–June 2022, where there were no observations, the calculated rates for 2023 were used.

Water flow simulations were carried out for 2021–2023. The simulated water level in the pond is controlled by a balance of inflows (precipitation and overland runoff) and outflows (evaporation, infiltration through the pond bottom and dam). To ensure realistic pond persistence during the multi-year simulation period, while preventing unrealistic complete drying while avoiding excessive overflow, we fitted the hydraulic conductivity of the clay liner at the pond bottom to a value of 0.0002 m d⁻¹. Increasing this parameter above 0.0002 m d⁻¹ resulted in excessive seepage losses, leading to a significant and unrealistic decline in the simulated pond water level over the simulation period, which was inconsistent with observed or expected pond behaviour in the study area.

The rest of the parameters are presented in Table 1. During periods with high precipitation, perched water was developed above the clay layer (around 0.5 m below the land surface, not shown). Daniels et al. (1978) reported that soil horizons having 10 % of platy plinthite will perch water.

Runoff is rarely observed in the area. The HGS model calculates fluid fluxes across the pond boundary. Water fluxes are computed between active nodes (located on the pond boundary – dark blue dots in Fig. 3a) and contributing nodes (located just outside the pond boundary). The calculated surface water flux represents the simulated runoff to the pond (Fig. 7).

At the beginning of 2021, three significant flow events occurred after intensive 30, 50, and 82 mm rainfalls on 18 February, 1–2 March, and 24 April, respectively. During the rest of the time, the average computed surface flow rate to the pond is around 4.4 m³ d⁻¹. The latter is a relatively small value given a 650 m-long pond perimeter. This small but persistent surface water inflow to the pond during dry periods (no precipitation), attributable to slow drainage of shallow subsurface lateral flow (interflow or return flow) from upslope areas that reaches the pond via surface pathways. This is distinct from precipitation-driven overland flow/surface runoff, which occurs only during or immediately following rainfall events (Tarboton, 2003).

Simulated changes to pond water volume (m³) and water level (m a.m.s.l.) were tracked over the study period (Fig. 8). The simulated minimal and maximal water levels were 109.03 and 109.37 m a.m.s.l. A rise in water level by 0.34 m causes an increase in water volume from 10 770 to 16 075 m³.

The HGS computed temporal E. coli fluxes entering the pond with surface water. The influxes of E. coli to the pond were visualized along with their calculated cumulative numbers over time for both sources of runoff (Fig. 12a) and direct excretion of feces (Fig. 12b). At the end of simulations, the number of bacteria entering the pond by manure excretion was around 130 times greater than by surface runoff. Simulations show that water flowed mainly from the pond into the subsoil, so that E. coli concentrations in the subsoil did not affect the water quality in the pond.

Simulated and observed concentrations of E. coli were each averaged over the interior and nearshore sampling locations (Fig. 13). Averaged values of concentrations at the nearshore locations (17–26) were approximately three times higher than the average of concentrations sampled at interior locations (1–15). Elevated nearshore concentrations may be explained by flushing bacteria to the pond during runoff and direct excretion by bathing cattle, which, according to monitoring, spent most of their time grouped close to the shore.

The summary data in Fig. 13 show that the model describes seasonal average concentration patterns relatively well. However, observed concentrations significantly declined during autumn 2022 and 2023 compared to the model simulation. Clear, shallow water can cause deeper penetration of solar radiation. de Brauwere et al. (2014) indicate that the inactivation of bacteria is caused by UV irradiation. To account for the latter, some models add a term to the overall decay parameter due to sunlight (McCorquodale et al., 2004) or use a decay term depending on the intensity of the solar radiation (Kashefipour et al., 2002). The decrease in the nutrients in water in the fall can also be the reason for the reduction of E. coli concentration.

The descriptive statistics of measured and simulated average concentrations were close when computed over the observation period. The minimum and maximum averages across the pond concentrations were 3.56 and 525.1 for observed and 4.08 and 479.4 MPN (100 mL) for simulated data, respectively. The mean logarithms of average concentrations were 1.70 ± 0.47 and 1.99 ± 0.67 for the measured and simulated data, respectively. The correlation coefficient between measured and simulated logarithms of average concentrations was 0.483. This value was significant at a 0.01 significance level and indicated a moderate correlation.