In 1914, the Morton Salt Company cleverly converted an 18th century English proverb (“it never rains but it pours”) into a successful marketing slogan (“when it rains, it pours”) (see e.g., Means, May 23, 2022; Meider, 2018; Barbour, 1963). Clever marketing aside, we generally understand the phrase to mean that when something bad happens, other bad things tend to happen at the same time. Among the many increased risks for farming from climate change is an increase in extreme precipitation, especially in the spring—2019 serves a recent reminder (Lee and Abatzoglou, 2023; US EPA, November 16, 2023; Time, August 11, 2023; Haverback and Curry, August 3, 2023; Gustin, May 2, 2021; NOAA, May 7, 2020; Schwartz, November 21, 2019; USDA, 2019; Yale, E360 Digest, May 2, 2019; Motha, 2011; Trenberth, 2011). With the proverbial “when it rains, it pours” in mind, we begin a series exploring recent research about the impacts of extreme participation on nutrient loss (Skidmore et al., 2023). The key takeaway is intuitive and critical: when something bad happens (extreme precipitation) the key to minimizing other bad from happening (nutrient loss) at the same time is to avoid excess nutrients being available to be lost. The farmer cannot control extreme events, but farmers do have some degree of control over whether excess nutrients are present on bare or frozen soils to be washed away. In other words, control what you can so that when it rains, it doesn’t pour. The following serves as background to the series of articles.
Background: Nutrient Loss 101
To begin this series, we briefly discuss the background on the process by which nutrients are lost from farming and fields. Nutrients include the basic elements such as nitrogen and phosphorus necessary for plant growth, many of which are supplied in modern farming by synthetic fertilizers applied to the fields. Excess nutrients can be exported from farm fields and remain a major natural resource concern for farmers, policymakers, and all of us who depend on clean water. For the farmer, lost nutrients are lost profits, and most farmers have little interest in polluting public waters. The cost of nitrogen, for example, can range from $193 per ton (anhydrous ammonia) to as much as $760 per ton and this cost can vary significantly as farmers have experienced in the last 15 years (see e.g., farmdoc daily, September 19, 2023; September 12, 2023; August 29, 2023; August 15, 2023; August 1, 2023; June 13, 2023; February 28, 2023). A farmer’s management of input cost such as fertilizer is a key driver of farm income, and USDA’s recent farm income forecasts are notable for the decline in fertilizer costs, helping overall farm income remain above average (USDA ERS, November 30, 2023).
Farmers face significant pressure to reduce nutrient losses for water quality reasons. High loads of nitrogen and phosphorus can lead to algae blooms in lakes and rivers (Chicago Tribune, November 18, 2021; The Gazette, October 2, 2022) or unsafe nitrate levels in private wells (PBS Wisconsin, December 1, 2022). For states in the Mississippi River watershed, runoff can reach the Gulf and contribute to the Gulf Hypoxic (or dead) Zone (NOAA). As one indication of the pressure to reduce nutrient losses, the States along the Mississippi have signed on to the Hypoxia Task Force and created state-level Nutrient Reduction Strategies (EPA). Illinois, for example, has operated a Nutrient Loss Reduction Strategy since 2015 (Illinois EPA, INLRS).
Arguably, the key finding for nutrient loss in research is consistent and has the added benefit of aligning with intuition and common sense: Nutrient losses nearly all occur during heavy rainfall and snow melt, particularly in non-irrigated production systems (Skidmore et al., 2023; Xia et al., 2020; Zopp et al., 2019). In Midwestern systems like Wisconsin, for example, half of all runoff comes from precipitation (either rain or snowmelt) when the ground was frozen (February and March), despite these only accounting for 11% of annual precipitation (USGS, 2011). On non-frozen ground, the highest runoff occurs in May and June, which is a period of “high-intensity and (or) repetitive rainfall events” leading to high soil moisture. Moreover, crop cover is minimal at the time.
Not all runoff creates the same nutrient losses. Runoff from frozen ground has the lowest concentration of suspended sediments, likely because there is less soil loss when the soil is frozen. This means the snowmelt losses are primarily of dissolved nutrients—these are nutrients sitting at the soil’s surface, waiting to run off. In contrast, rainfall in May and June delivers more suspended sediment to surface water systems. These sediments include “legacy nutrients” that may have been applied decades ago and are still bound to soil today (Motew et al., 2017, Gentry et al., 2007). Furthermore, rain on frozen or bare ground leads to runoff, particularly when nutrients were spread since the last harvest. These conditions are perfect for overland flow, or transport of nutrients and soils along the surface to nearby streams.
Extreme precipitation events are also a big factor for nutrient and soil losses. Rain events categorized as ten-year-or-less (i.e., those we expect to occur at least once in every ten years) generate runoff 66% of the time. Twenty-five-or-more-year events generate runoff 82% of the time. Moreover, extreme events are more likely to generate soil loss, even compared to their impact on nutrient loss (Wisconsin Discovery Farms, 2021). Soil loss has a magnifying effect for nutrient loss, creating a feedback loop. For one, soil erosion is costly to farmers, and one study found that US corn growers spend half a billion dollars per year on fertilizer to make up for soil erosion (Jang et al., 2020). Moreover, researchers at North Dakota State estimate that 1 inch of lost topsoil costs $688 per acre in lost nutrients. These nutrients likely end up in surface water, further exacerbating water quality problems (Franzen, July 21, 2021).
The overarching findings of these and other studies is the importance of the soil conditions and practices at the time of precipitation. Precipitation on bare ground is a recipe for higher runoff, higher soil losses, and more sediment transport. In contrast, healthy soils—and especially those soils protected by crop cover—are less vulnerable to the heavy losses we observe around extreme precipitation events (Farm Progress, September 27, 2017). The bottom line also aligns with intuition and common sense: the weather is not in the farmer’s control, nor can they do much about extreme precipitation and weather events that may only get worse with climate change. But some things are in the farmer’s control: the farmer can take steps to decrease the amount of nutrients sitting on bare and frozen soils for snow melt, spring rains, and extreme events.
For nutrient losses, the key is controlling what can be controlled. Keep soils healthy and prevent erosion, as well as avoid excess nutrients on bare and frozen ground. Practices like cover cropping, conservation tillage, and buffer strips all have been shown to reduce nutrient loss. These practices, of course, come with costs. Conservation practices may also increase managerial challenges and production risk. Importantly, such practices are also investments in the soils, the fields, and the farm, in addition to reducing losses.
Source: illinois.edu
Photo Credit: gettyimages-kotenko-a
Categories: Illinois, Crops, Weather