Agriculture and Irrigation in the United States
According to a U.S. Geological Survey report, agriculture is a major user of ground and surface water in the United States, and irrigation accounted for 42 percent of the Nation’s total freshwater withdrawals in 2015. Water applied as irrigation allows for crop production in arid regions and supplements soil moisture in humid regions when growing season precipitation is insufficient. Irrigation has enhanced both the productivity and profitability of the agricultural sector. According to the 2017 Census of Agriculture, farms with some form of irrigation accounted for more than 54 percent of the total value of U.S. crop sales, while irrigated land accounted for less than 20 percent of harvested cropland. Irrigated crop production helps to support local rural economies in many areas of the U.S., and contributes to the Nation’s livestock, food processing, transportation, and energy sectors.
Where Does U.S. Crop Irrigation Occur?
The 2017 Census of Agriculture reported total U.S. irrigated cropland at 58 million acres. Much of the irrigated land is concentrated in the western U.S. where the production of many crops requires irrigation. Irrigation is also common in the southeastern U.S., particularly along the Mississippi River Valley in Arkansas, Louisiana, and Tennessee as well as southern Georgia and central Florida. Where irrigation occurs depends on regional cropping patterns, local climatic conditions as well as the availability of surface and groundwater resources.
Top States for Irrigated Land
- Nebraska – 8.6 million acres
- California – 7.8 million acres
- Arkansas – 3.4 million acres
- Texas – 3.1 million acres
- Idaho – 2.7 million acres
How Has Irrigation Evolved Over Time?
The importance of irrigation for U.S. agricultural production has evolved over the past century. Since 1890, irrigated acreage nationwide has grown from less than 3 million acres to over 58 million acres in 2017. Expansion in the nation’s irrigated land was attributable, in part, to federal, State and local water development projects as well as innovations in groundwater pumping technologies. More recently, the intensity of irrigation (measured as the nationwide average of water use per acre irrigated) has declined in response to regional shifts in area irrigated, changing cropping patterns, and improved efficiency in water application technologies. Between 1969 and 2017, the average irrigation application rate declined from more than 2 acre feet per acre irrigated to just under 1.5 acre feet per acre irrigated (1 acre-foot = 325,851 gallons).
Which Crops Are Irrigated?
Irrigation water allocations by crop reflect climate and crop-water consumptive requirements as well as shifting market conditions. In 2017, corn grown for grain accounted for the most irrigated acreage in the U.S. with more than 12 million irrigated acres harvested. Soybeans accounted for the second most irrigated acreage in 2017 with more than 9 million irrigated acres harvested. The shift reflects expanding market demand for corn and soybeans as livestock feed and source for biofuel, as well as the broader eastern shift of irrigated agriculture where variable growing season rainfall promotes irrigating corn and soybean crops.
What Sources of Water Does Irrigated Agriculture Use?
Irrigated agriculture relies on both surface water and groundwater to support crop production. According to the 2018 Irrigation and Water Management Survey, more than half of all water applied as irrigation came from surface water with the remaining water obtained from groundwater sources. Surface water-fed irrigation is most common in the western U.S. where federal reclamation policy and State investments in irrigation infrastructure have harnessed the region’s surface water resources.
In many of the most prominent irrigated agricultural regions of the U.S, on-farm water withdrawals are generally supplied or managed by a local irrigation organization. Water delivery organizations operate water storage and conveyance systems used to supply water to irrigated farms. Groundwater organizations help to manage irrigation pumping from local groundwater resources. The USDA’s 2019 Survey of Irrigation Organizations provides a nationally representative look at these irrigation water supply organizations. The majority of irrigation organizations deliver water to farms as their primary function. More than one quarter of all organizations manage on-farm groundwater withdrawals for irrigation. Many organizations provide the dual functions of water supply delivery and groundwater management. Irrigation organizations may also provide important secondary functions such as electricity generation and water management for recreation purposes or wildlife habitat.
How Are Crops Irrigated?
Various methods are used to apply irrigation water to crops, which can be broadly categorized as gravity or pressurized systems. Gravity irrigation systems use on-field furrows or basins to advance water across the field surface through gravity-means only. Pressurized systems apply water under pressure through pipes or other tubing directly to crops. Pressurized irrigation includes acres irrigated by sprinkler and micro/drip irrigation systems. Under many field conditions, pressurized irrigation systems are generally more water-use efficient than gravity systems as less water is lost to evaporation, deep percolation and field runoff. Over the last 30 years the conversion of gravity to pressurized irrigation systems has increased. In 1984, 37 percent of all irrigated cropland acres in the western U.S. used pressurized irrigation systems, as compared with 72 percent in 2018.
SDGs, Targets, and Indicators
1. Which SDGs are addressed or connected to the issues highlighted in the article?
- SDG 6: Clean Water and Sanitation
- SDG 8: Decent Work and Economic Growth
- SDG 12: Responsible Consumption and Production
- SDG 13: Climate Action
- SDG 15: Life on Land
2. What specific targets under those SDGs can be identified based on the article’s content?
- SDG 6.4: By 2030, substantially increase water-use efficiency across all sectors and ensure sustainable withdrawals and supply of freshwater to address water scarcity.
- SDG 8.4: Improve progressively, through 2030, global resource efficiency in consumption and production and endeavor to decouple economic growth from environmental degradation.
- SDG 12.4: By 2020, achieve the environmentally sound management of chemicals and all wastes throughout their life cycle, in accordance with agreed international frameworks, and significantly reduce their release to air, water, and soil in order to minimize their adverse impacts on human health and the environment.
- SDG 13.1: Strengthen resilience and adaptive capacity to climate-related hazards and natural disasters in all countries.
- SDG 15.1: By 2020, ensure the conservation, restoration, and sustainable use of terrestrial and inland freshwater ecosystems and their services, in particular forests, wetlands, mountains, and drylands, in line with obligations under international agreements.
3. Are there any indicators mentioned or implied in the article that can be used to measure progress towards the identified targets?
- Indicator 6.4.1: Change in water-use efficiency over time.
- Indicator 8.4.1: Material footprint, material footprint per capita, and material footprint per GDP.
- Indicator 12.4.1: Number of parties to international multilateral environmental agreements on hazardous waste, and the extent of their implementation.
- Indicator 13.1.1: Number of deaths, missing persons, and directly affected persons attributed to disasters per 100,000 population.
- Indicator 15.1.1: Forest area as a proportion of total land area.
Table: SDGs, Targets, and Indicators
| SDGs | Targets | Indicators |
|---|---|---|
| SDG 6: Clean Water and Sanitation | 6.4: By 2030, substantially increase water-use efficiency across all sectors and ensure sustainable withdrawals and supply of freshwater to address water scarcity. | 6.4.1: Change in water-use efficiency over time. |
| SDG 8: Decent Work and Economic Growth | 8.4: Improve progressively, through 2030, global resource efficiency in consumption and production and endeavor to decouple economic growth from environmental degradation. | 8.4.1: Material footprint, material footprint per capita, and material footprint per GDP. |
| SDG 12: Responsible Consumption and Production | 12.4: By 2020, achieve the environmentally sound management of chemicals and all wastes throughout their life cycle, in accordance with agreed international frameworks, and significantly reduce their release to air, water, and soil in order to minimize their adverse impacts on human health and the environment. | 12.4.1: Number of parties to international multilateral environmental agreements on hazardous waste, and the extent of their implementation. |
| SDG 13: Climate Action | 13.1: Strengthen resilience and adaptive capacity to climate-related hazards and natural disasters in all countries. | 13.1.1: Number of deaths, missing persons, and directly affected persons attributed to disasters per 100,000 population. |
| SDG 15: Life on Land | 15.1: By 2020, ensure the conservation, restoration, and sustainable use of terrestrial and inland freshwater ecosystems and their services, in particular forests, wetlands, mountains, and drylands, in line with obligations under international agreements. | 15.1.1: Forest area as a proportion of total land area. |
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Fuente: ers.usda.gov
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