In animal husbandry, a concentrated animal feeding operation (CAFO), as defined by the United States Department of Agriculture (USDA), is an intensive animal feeding operation (AFO) in which over 1,000 animal units are confined for over 45 days a year. An animal unit is the equivalent of 1,000 pounds of "live" animal weight. [1] A thousand animal units equates to 700 dairy cows, 1,000 meat cows, 2,500 pigs weighing more than 55 pounds (25 kg), 10,000 pigs weighing under 55 pounds, 10,000 sheep, 55,000 turkeys, 125,000 chickens, or 82,000 egg laying hens or pullets. [2]
CAFOs are governed by regulations that restrict how much waste can be distributed and the quality of the waste materials. [2] As of 2012 there were around 212,000 AFOs in the United States, [3] : 1.2 19,496 of which were CAFOs. [4] [a]
Livestock production has become increasingly dominated by CAFOs in the United States and other parts of the world. [5] Most poultry was raised in CAFOs starting in the 1950s, and most cattle and pigs by the 1970s and 1980s. [6] By the mid-2000s CAFOs dominated livestock and poultry production in the United States, and the scope of their market share is steadily increasing. In 1966, it took 1 million farms to house 57 million pigs; by 2001, it took only 80,000 farms to house the same number. [7] [8]
There are roughly 212,000 AFOs in the United States, [3] : 1.2 of which 19,496 met the more narrow criteria for CAFOs in 2016. [4] The Environmental Protection Agency (EPA) has delineated three categories of CAFOs, ordered in terms of capacity: large, medium and small. The relevant animal unit for each category varies depending on species and capacity. For instance, large CAFOs house 1,000 or more cattle, medium CAFOs can have 300–999 cattle, and small CAFOs harbor no more than 300 cattle. [9]
The table below provides some examples of the size thresholds for CAFOs:
Animal Sector | Large CAFOs | Medium CAFOs | Small CAFOs |
---|---|---|---|
Cattle or cow/calf pairs | 1,000 or more | 300–999 | Less than 300 |
Mature dairy cattle | 700 or more | 200–699 | Less than 200 |
Swine (weighing over 55 lb) | 2,500 or more | 750–2,499 | Less than 750 |
Turkeys | 55,000 or more | 16,500–54,999 | Less than 16,500 |
Laying hens or broilers (liquid manure handling systems) | 30,000 or more | 9,000–29,999 | Less than 9,000 |
Chickens other than laying hens (other than a liquid manure handling systems) | 125,000 or more | 37,500–124,999 | Less than 37,500 |
Laying hens (other than a liquid manure handling systems) | 82,000 or more | 25,000–81,999 | Less than 25,000 |
The categorization of CAFOs affects whether a facility is subject to regulation under the Clean Water Act (CWA). EPA's 2008 rule specifies that "large CAFOs are automatically subject to EPA regulation; medium CAFOs must also meet one of two 'method of discharge' criteria to be defined as a CAFO (or may be designated as such); and small CAFOs can only be made subject to EPA regulations on a case-by-case basis." [9] A small CAFO will also be designated a CAFO for purposes of the CWA if it discharges pollutants into waterways of the United States through a man-made conveyance such as a road, ditch or pipe. Alternatively, a small CAFO may be designated an ordinary animal feeding operation (AFO) once its animal waste management system is certified at the site.
Since it first coined the term, the EPA has changed the definition (and applicable regulations) for CAFOs on several occasions. Private groups and individuals use the term CAFO colloquially to mean many types of both regulated and unregulated facilities, both inside and outside the U.S. The definition used in everyday speech may thus vary considerably from the statutory definition in the CWA. CAFOs are commonly characterized as having large numbers of animals crowded into a confined space, a situation that results in the concentration of manure in a small area.
The EPA has focused on regulating CAFOs because they generate millions of tons of manure every year. When improperly managed, the manure can pose substantial risks to the environment and public health. [10] In order to manage their waste, CAFO operators have developed agricultural wastewater treatment plans. The most common type of facility used in these plans, the anaerobic lagoon, has significantly contributed to environmental and health problems attributed to the CAFO. [11]
The large amounts of animal waste from CAFOs present a risk to water quality and aquatic ecosystems. [12] States with high concentrations of CAFOs experience on average 20 to 30 serious water quality problems per year as a result of manure management issues. [13]
Animal waste includes a number of potentially harmful pollutants. Pollutants associated with CAFO waste principally include:
The two main contributors to water pollution caused by CAFOs are soluble nitrogen compounds and phosphorus. The eutrophication of water bodies from such waste is harmful to wildlife and water quality in aquatic system like streams, lakes, and oceans. [15]
Groundwater and surface water are closely linked, so polluting one often affects the other. [13] Surface water may be polluted by CAFO waste through the runoff of nutrients, organics, and pathogens from fields and storage. Waste can be transmitted to groundwater through the leaching of pollutants. [16] Some facility designs, such as lagoons, can reduce the risk of groundwater contamination, but the microbial pathogens from animal waste may still pollute surface and groundwater, harming wildlife and human health. [17]
A CAFO is responsible for one of the biggest environmental spills in U.S. history. In 1995, a 120,000-square-foot (11,000 m2) lagoon ruptured in North Carolina. North Carolina contains a lot of the United States' industrial hog operations, which disproportionally impact Black, Hispanic and Indian American residents. [18] The spill released 25.8 million US gallons (98,000 m3) of effluvium into the New River [19] and killed 10 million local fish. The spill also contributed to an outbreak of Pfiesteria piscicida, which caused health problems in nearby humans, including skin irritation and short-term cognitive problems. [20]
CAFOs reduce ambient air quality. They release several gases harmful to humans: ammonia, hydrogen sulfide, methane, and particulate matter. Larger CAFOs release more gas, mostly by the decomposition of large stores of animal manure. [13] CAFOs also emit strains of antibiotic resistant bacteria into the surrounding air, particularly downwind. Levels of antibiotics measured downwind from swine CAFOs were three times higher than those measured upwind. [21] The source is not widely known, but animal feed is suspected. [22]
Globally, ruminant livestock are responsible for about 115 Tg/a of the 330 Tg/a (35%) of anthropogenic greenhouse gas emissions released per year. [23] Livestock operations are responsible for about 18% of greenhouse gas emissions globally and over 7% of greenhouse gas emissions in the U.S. [24] Methane is the second most concentrated greenhouse gas contributing to global climate change, [25] with livestock contributing nearly 30% of anthropogenic methane emissions. [26] Only 17% of livestock-related emissions come from manure, whereas most come from enteric fermentation or gases produced during digestion. [26] 76% of bacteria grown within a swine CAFO are Staphylococcus Aureus, [21] followed by Group A Streptococci and Fecal Coliforms. [21]
The Intergovernmental Panel on Climate Change (IPCC) acknowledges the big effect of livestock on methane emissions, antibiotic resistance, and climate change. To reduce emissions, it recommends removing sources of stress and changing how animals are fed, including sources of feed grain, amount of forage, and amount of digestible nutrients. [27] The Humane Society of the United States (HSUS) argues for reducing use of non-therapeutic antibiotics, especially those that are widely used in human medicine, on the advice of over 350 organizations including the American Medical Association. [28] If no change is made and methane emissions continue increasing in direct proportion to the number of livestock, global methane production is predicted to increase by 60% by 2030. [29] Greenhouse gases and climate change make air worse, causing illnesses such as respiratory disorders, lung tissue damage, and allergies. [30] Reducing the increase of greenhouse gas emissions from livestock could rapidly curb global warming. [31] Also, people near CAFOs often complain of the smell, which comes from a complex mixture of ammonia, hydrogen sulfide, carbon dioxide, and volatile and semi-volatile organic compounds.
Waste disposal also makes air worse. Some CAFOs will use "spray fields" and pump the waste of thousands of animals into a machine that sprays it onto an open field. The spray can be carried by wind onto nearby homes, depositing pathogens, heavy metals, and antibiotic resistant bacteria into the air of poor or minority communities. It often contains respiratory and eye irritants including hydrogen sulfide and ammonia. [32]
The economic role of CAFOs has expanded significantly in the U.S. in the past few decades, and there is clear evidence that CAFOs have come to dominate animal production industries. The rise in large-scale animal agriculture began in the 1930s with the modern mechanization of swine slaughterhouse operations. [33]
The growth of corporate contracting has also contributed to a transition from a system of many small-scale farms to one of relatively few large industrial-scale farms. This has dramatically changed the animal agricultural sector in the United States. According to the National Agricultural Statistics Service, "In the 1930s, there were close to 7 million farms in the United States and as of the 2002 census, just over 2 million farms remain." [34] From 1969 to 2002, the number of family farms dropped by 39%, [35] yet the percentage of family farms has remained high. As of 2004, 98% of all U.S. farms were family-owned and -operated. [36] Most meat and dairy products are now produced on large farms with single-species buildings or open-air pens. [37]
Due to their increased efficiency, CAFOs provide a source of low cost animal products: meat, milk and eggs. CAFOs may also stimulate local economies through increased employment and use of local materials in their production. [38] The development of modern animal agriculture has increased the efficiency of raising meat and dairy products. Improvements in animal breeding, mechanical innovations, and the introduction of specially formulated feeds (as well as animal pharmaceuticals) have contributed to the decrease in cost of animal products to consumers. [39] The development of new technologies has also helped CAFO owners reduce production cost and increase business profits with less resources consumption. The growth of CAFOs has corresponded with an increase in the consumption of animal products in the United States. According to author Christopher L. Delgado, "milk production has doubled, meat production has tripled, and egg production has increased fourfold since 1960" in the United States. [40]
Along with the noted benefits, there are also criticisms regarding CAFOs' impact on the economy. Many farmers in the United States find that it is difficult to earn a high income due to the low market prices of animal products. [41] Such market factors often lead to low profit margins for production methods and a competitive disadvantage against CAFOs. Alternative animal production methods, like "free range" or "family farming" operations [42] are losing their ability to compete, though they present few of the environmental and health risks associated with CAFOs.
The price of meat does not reflect the negative ecological impacts that result from industrial agricultural systems. [43] [44] The negative production externalities (when market prices inappropriately reflect or hide the societal harms incurred in the creation of a product [45] ) of CAFOs include damaging effects to the environment caused by, among others, ever-increasing amounts of often poorly managed waste. [5] The costs from damage caused to the atmosphere (in the form of GHGs), water, soil, fisheries, and recreational areas, estimated at hundreds of billions of dollars, are typically not incurred by corporations that feature the use of CAFOs in their business models. [5] Additionally, human antimicrobial resistance from antibiotic use in industrial animal agriculture represents a serious risk to societal wellbeing. [45] Corporations that rely on using CAFOs through contract farming have an unfair economic advantage because the costs of managing animal waste is shifted to contract farmers and, when spills occur, to the areas surrounding them.[ citation needed ] Property values near CAFOs may plummet considerably due to the detrimental impacts that CAFOs can have on air, water, and land in the nearby areas. [46] For instance, researchers found that there is a statistically significant relationship between property values declines and CAFO proximity. [47]
Critics of CAFOs also maintain that CAFOs benefit from industrial and agricultural tax breaks and subsidies, and the "vertical integration of giant agribusiness firms". [48] The U.S. Department of Agriculture (USDA), for instance, spent an average of $16 billion annually between FY 1996 to FY 2002 on commodity-based subsidies. [49] Lax enforcement of anti-competitive practices may be helping create a market monopoly. Critics also contend that CAFOs cut costs by overusing antibiotics. [50]
The direct discharge of manure from CAFOs and the accompanying pollutants (including nutrients, antibiotics, pathogens, and arsenic) is a serious public health risk. [51] The contamination of groundwater with pathogenic organisms from CAFOs can threaten drinking water safety, and contamination of drinking water with pathogens can cause outbreaks of infectious disease. The EPA estimates that 53% of the United States population drinks groundwater. [52]
Contamination of water by CAFOs causes various heart problems. Accidental ingestion of contaminated water can result in diarrhea or other gastrointestinal illnesses. Dermal exposure can result in irritation and infection of the skin, eyes or ear. [53] High levels of nitrate in drinking water are associated with increased risk of hyperthyroidism, insulin-dependent diabetes, and central nervous system malformations. [53]
Antibiotic contamination also threatens human health. [12] To maximize animal production, CAFOs are using ever more antibiotics, which in turn increases bacterial resistance. This resistance makes it harder to treat bacterial infections. Contaminated surface water and groundwater is particularly concerning, as these can spread antibiotic-resistant bacteria. [54] Antibiotic resistance can result due to DNA mutations, transformations and conjugations arising from various antibiotics and pharmaceutical drugs found in drinking water. [54]
Antibiotics are used heavily in CAFOs to both treat and prevent illness in individual animals as well as groups. Animals in CAFOs are closer together, so pathogens spread easily. Even if their stock are not sick, CAFOs put low doses of antibiotics into feed "to reduce the chance for infection and to eliminate the need for animals to expend energy fighting off bacteria, with the assumption that saved energy will be translated into growth". [38] This is a non-therapeutic use of antibiotics. Such antibiotic use is thought to allow animals to grow faster and bigger, increasing the CAFO's output. Regardless, the World Health Organization has recommended that the non-therapeutic use of antibiotics in animal husbandry be reevaluated, as such antibiotic overuse breeds antibiotic-resistant bacteria. [55] [56] [57] When bacteria in or around animals are exposed to antibiotics, natural selection favours the spread of mutations with greater resistance. [58] Use of antibiotics by CAFOs thus increases antimicrobial resistance. This threatens public health because resistant bacteria generated by CAFOs can be spread to the surrounding environment and communities via waste water discharge or the aerosolization of particles. [59]
Air pollution caused by CAFOs can cause asthma, headaches, respiratory problems, eye irritation, nausea, weakness, and chest tightness. These affect farm workers and nearby residents, including children. [60] The risks to nearby residents were highlighted in a study evaluating health outcomes of more than 100,000 individuals living in regions with high densities of CAFOs, finding a higher prevalence of pneumonia and unspecified infectious diseases in those with high exposures compared to controls. [61] Furthermore, a Dutch cross-sectional study 2,308 adults found decreases in residents' lung function to be correlated with increases of particle emissions by nearby farms. [62] In regards to workers, multiple respiratory consequences should be noted. Although "in many big CAFOs, it takes only a few workers to run a facility housing thousands of animals," [63] the long exposure and close contact to animals puts CAFO employees at an increased risk. This includes a risk of contracting diseases like Novel H1N1 flu, which erupted globally in spring of 2009, [64] or MRSA, a strain of antibiotic resistant bacteria. [56] For instance, livestock-associated MRSA has been found in the nasal passages of CAFO workers, on the walls of the facilities they work in, and in the animals they tend. [56] In addition, individuals working in CAFOs are at risk for chronic airway inflammatory diseases secondary to dust exposure, with studies suggesting the possible benefits to utilizing inhaler treatments empirically. [65] Studies conducted by the University of Iowa show that the asthma rate of children of CAFO operators is higher than that of children from other farms. [66]
Low income and minority populations suffer disproportionately from proximity to CAFO and pollution and waste. [32] These populations suffer the most due to their lack of political clout to oppose construction of CAFOs and are often not economically capable of simply moving somewhere else.
In southern United States, the "Black Belt", a roughly crescent-shaped geological formation of dark fertile soil in the Southern United States well suited to cotton farming, has seen the long-lasting effects of slavery. During and after the Civil War, this area consisted mostly of black people who worked as sharecroppers and tenant farmers. Due to ongoing discrimination in land sales and lending, many African American farmers were systematically deprived of farmland. Today, communities in the Black Belt experience poverty, poor housing, unemployment, poor health care and have little political power when it comes to the building of CAFOs. Black and brown people living near CAFOs often lack the resources to leave compromised areas and are further trapped by plummeting property values and poor quality of life. [67] In addition to financial problems, CAFOs are also protected by "right-to-farm" law that protects them from residents that are living in CAFO occupied communities. [68]
Not only are communities surrounded negatively affected by CAFOs, but the workers themselves experience harm from being on the job. In a study done in North Carolina that focused on twenty one Latino chicken catchers for a poultry-processing plant, the work place was found to be forcefully high intensity labor with high potential for injury and illness including trauma, respiratory illness, drug use and musculoskeletal injuries. Workers were also found to have little training about the job or safety. [69] In the United States, agricultural workers are engaged in one of the most hazardous jobs in the country. [70]
CAFO workers have historically been African American but there has been a surge of Hispanic and often undocumented Hispanic workers. Between 1980 and 2000, there was a clear shift in an ethnic and racially diverse workforce, led by Hispanic workforce growth.[7] Oftentimes, CAFO owners will preferably hire Hispanic workers because they are low-skilled workers who are willing to work longer hours and do more intensive work. Due to this, there are increased ICE raids on meat processing plants.
CAFO practices have raised concerns over animal welfare from an ethics standpoint. Some view such conditions as neglectful to basic animal welfare. According to David Nibert, professor of sociology at Wittenberg University, more than 10 billion animals are housed in "horrific conditions" in more than 20,000 CAFOs across the U.S. alone, where they "spend their last 100–120 days crammed together by the thousands standing in their own excrement, with little or no shelter from the elements." [71] Many people believe that the harm to animals before their slaughter should be addressed through public policy. [72] Laws regarding animal welfare in CAFOs have already been passed in the United States. For instance, in 2002, the state of Florida passed an amendment to the state's constitution banning the confinement of pregnant pigs in gestation crates. [73] As a source for comparison, the use of battery cages for egg-laying hens and battery cage breeding methods have been completely outlawed in the European Union since 2012. [74]
Whereas some people are concerned with animal welfare as an end in itself, others are concerned about animal welfare because of the effect of living conditions on consumer safety. Animals in CAFOs have lives that do not resemble those of animals found in the wild. [75] Although CAFOs help secure a reliable supply of animal products, the quality of the goods produced is debated, with many arguing that the food produced is unnatural. For instance, confining animals into small areas requires the use of large quantities of antibiotics to prevent the spread of disease. There are debates over whether the use of antibiotics in meat production is harmful to humans. [76]
Since 1960 average cow's milk production has increased from 5-kilogram /day (11 lb) to 30-kilogram /day (66 lb) by 2008, as noted by Dale Bauman and Jude Capper in the Efficiency of Dairy Production and its Carbon Footprint. The article points to the fact that the carbon footprint resulting from the production of a gallon of milk in 2007 is 37% of what it was in 1944. [77]
The command-and-control permitting structure of the Clean Water Act (CWA) provides the basis for nearly all regulation of CAFOs in the United States. Generally speaking, the CWA prohibits the discharge of pollution to the "waters of the United States" from any "point source", unless the discharge is authorized by a National Pollutant Discharge Elimination System (NPDES) permit issued by the EPA (or a state delegated by the EPA). CAFOs are explicitly listed as a point source in the CWA. [78] Unauthorized discharges made from CAFOs (and other point sources) violate the CWA, even if the discharges are "unplanned or accidental." [79] CAFOs that do not apply for NPDES permits "operate at their own risk because any discharge from an unpermitted CAFO (other than agricultural stormwater) is a violation of the CWA subject to enforcement action, including third party citizen suits." [80]
The benefit of an NPDES permit is that it provides some level of certainty to CAFO owners and operators. "Compliance with the permit is deemed compliance with the CWA... and thus acts as a shield against EPA or State CWA enforcement or against citizen suits under... the CWA." [80] In addition, the "upset and bypass" provisions of the permit can give permitted CAFO owners a legal defense when "emergencies or natural disasters cause discharges beyond their reasonable control." [80]
Under the CWA, the EPA specifies the maximum allowable amounts of pollution that can be discharged by facilities within an industrial category (like CAFOs). These general "effluent limitations guidelines" (ELG) then dictate the terms of the specific effluent limitations found in individual NPDES permits. The limits are based on the performance of specific technologies, but the EPA does not generally require the industry to use these technologies. Rather, the industry may use "any effective alternatives to meet the pollutant limits." [81]
The EPA places minimum ELG requirements into each permit issued for CAFOs. The requirements can include both numeric discharge limits (the amount of a pollutant that can be released into waters of the United States) and other requirements related to ELGs (such as management practices, including technology standards). [82]
The major CAFO regulatory developments occurred in the 1970s and in the 2000s. The EPA first promulgated ELGs for CAFOs in 1976. [79] The 2003 rule issued by the EPA updated and modified the applicable ELGs for CAFOs, among other things. In 2005, the court decision in Waterkeeper Alliance v. EPA (see below) struck down parts of the 2003 rule. The EPA responded by issuing a revised rule in 2008.
A complete history of EPA's CAFO rulemaking activities is provided on the CAFO Rule History page. [83]
The Federal Water Pollution Control Act of 1948 was one of the first major efforts of the U.S. federal government to establish a comprehensive program for mitigating pollution in public water ways. The writers of the act aimed to improve water quality for the circulation of aquatic life, industry use, and recreation. Since 1948, the Act has been amended many times to expand programming, procedures, and standards. [84]
President Richard Nixon's executive order, Reorganization Plan No. 3, created the EPA in 1970. The creation of the EPA was an effort to create a more comprehensive approach to pollution management. As noted in the order, a single polluter may simultaneously degrade a local environment's air, water, and land. President Nixon noted that a single government entity should be monitoring and mitigating pollution and considering all effects. As relevant to CAFO regulation, the EPA became the main federal authority on CAFO pollution monitoring and mitigation. [85]
Congress passed the CWA in 1972 when it reworked the Federal Water Pollution Control Amendments. [86] It specifically defines CAFOs as point source polluters and required operations managers and/or owners to obtain NPDES permits in order to legally discharge wastewater from its facilities. [87]
The EPA began regulating water pollution discharges from CAFOs following passage of the 1972 CWA. ELGs for feedlot operations were promulgated in 1974, placing emphasis on best available technology in the industry at the time. [88] [ failed verification ] In 1976 EPA began requiring all CAFOs to be first defined as AFOs. From that point, if the specific AFO met the appropriate criteria, it would then be classified as a CAFO and subject to appropriate regulation. That same year, EPA defined livestock and poultry CAFO facilities and established a specialized permitting program. [89] NPDES permit procedures for CAFOs were also promulgated in 1976. [90]
Prior to 1976, size had been the main defining criteria of CAFOs. However, after the 1976 regulations came into effect, the EPA stipulated some exceptions. Operations that were identified as particularly harmful to federal waterways could be classified as CAFOs, even if the facilities' sizes fall under AFOs standards. Additionally, some CAFOs were not required to apply for wastewater discharge permits if they met the two major operational-based exemptions. The first exception applied to operations that discharge wastewater only during a 25-year, 24-hour storm event. (The operation only discharges during a 24-hour rainfall period that occurs once every 25 years or more on average.) The second exception was when operations apply animal waste onto agricultural land. [89]
In 1989, the Natural Resources Defense Council and Public Citizen filed a lawsuit against the EPA (and Administrator of the EPA, William Reilly). The plaintiffs claimed the EPA had not complied with the CWA with respect to CAFOs. [89] The lawsuit, Natural Resources Defense Council v. Reilly (D.D.C. 1991), resulted in a court order mandating the EPA update its regulations. They did so in what would become the 2003 Final Rule. [91]
In 1995, the EPA released a "Guide Manual on NPDES Regulations for Concentrated Animal Feeding Operations" to provide more clarity to the public on NPDES regulation after the EPA's report "Feedlots Case Studies of Selected States" revealed there was uncertainty in the public regarding CAFO regulatory terminology and criteria. [87] Although the document is not a rule, it did offer insight and furthered public understanding of previous rules.
In his 1998 Clean Water Action Plan, President Bill Clinton directed the USDA and the EPA to join forces to develop a framework for future actions to improve national water quality standards for public health. The two federal agencies' specific responsibility was to improve the management of animal waste runoff from agricultural activities. In 1998, the USDA and the EPA hosted eleven public meetings across the country to discuss animal feeding operations (AFOs). [92]
On March 9, 1999, the agencies released the framework titled the Unified National Strategy for Animal Feeding Operations. [93] In the framework, the agencies recommended six major activities to be included in operations' Comprehensive Nutrient Management Plans (CNMPs):
The framework also outlined two types of related programs. First, "voluntary programs" were designed to assist AFO operators with addressing public health and water quality problems. [94] The framework outlines three types of voluntary programs available: "locally led conservation," "environmental education," and "financial and technical assistance." [94] The framework explained that those that participate in voluntary programs are not required to have a comprehensive nutrient management plan (CNMP). The second type of program outlined by the framework was regulatory, which includes command-and-control regulation with NPDES permitting. [94]
EPA's 2003 rule updated decades-old policies to reflect new technology advancements and increase the expected pollution mitigation from CAFOs. [95] The EPA was also responding to a 1991 court order based on the district court's decision in Natural Resources Defense Council v. Reilly. [89] The final rule took effect on April 14, 2003, and responded to public comments received following the issuance of the proposed rule in 2000. [96] The EPA allowed authorized NPDES states until February 2005 to update their programs and develop technical standards. [96]
The 2003 rule established "non-numerical best management practices" (BMPs) for CAFOs that apply both to the "production areas" (e.g. the animal confinement area and the manure storage area) and, for the first time ever, to the "land application area" (land to which manure and other animal waste is applied as fertilizer). [97] [98] The standards for BMPs in the 2003 rule vary depending on the regulated area of the CAFO:
The 2003 rule also requires CAFOs to submit an annual performance report to the EPA and to develop and implement a comprehensive nutrient management plan (NMP) for handling animal waste. [98] Lastly, in an attempt to broaden the scope of regulated facilities, the 2003 rule expanded the number of CAFOs required to apply for NPDES permits by making it mandatory for all CAFOs (not just those who actually discharge pollutants into waters of the United States). [98] Many of the provisions of the rule were affected by the Second Circuit's decision issued in Waterkeeper Alliance v. EPA.
Environmental and farm industry groups challenged the 2003 final rule in court, and the Second Circuit Court of Appeals issued a decision in the consolidated case Waterkeeper Alliance, Inc. v. EPA, 399 F.3d 486 (2nd Cir. 2005). The Second Circuit's decision reflected a "partial victory" for both environmentalists and industry, as all parties were "unsatisfied to at least some extent" with the court's decision. [99] The court's decision addressed four main issues with the 2003 final rule promulgated by the EPA:
The EPA published revised regulations that address the Second Circuit court's decision in Waterkeeper Alliance, Inc. v. EPA on November 20, 2008 (effective December 22, 2008). [107] The 2008 final rule revised and amended the 2003 final rule.
The 2008 rule addresses each point of the court's decision in Waterkeeper Alliance v. EPA. Specifically, the EPA adopted the following measures:
The 2008 final rule also specifies two approaches that a CAFO may use to identify the "annual maximum rates of application of manure, litter, and process wastewater by field and crop for each year of permit coverage." The linear approach expresses the rate in terms of the "amount of nitrogen and phosphorus from manure, litter, and process wastewater allowed to be applied." The narrative rate approach expresses the amount in terms of a "narrative rate prescribing how to calculate the amount of manure, litter, and process wastewater allowed to be applied. [80] The EPA believes that the narrative approach gives CAFO operators the most flexibility. Normally, CAFO operators are subject to the terms of their permit for a period of 5 years. Under the narrative approach, CAFO operators can use "real time" data to determine the rates of application. As a result, CAFO operators can more easily "change their crop rotation, form and source of manure, litter, and process wastewater, as well as the timing and method of application" without having to seek a revision to the terms of their NPDES permits. [80]
The EPA points to several tools available to assist CAFO operators in meeting their obligations under the CWA. First, the EPA awards federal grants to provide technical assistance to livestock operators for preventing discharges of water pollution (and reducing air pollution). The EPA claims that CAFOs can obtain an NMP for free under these grants. [111] Recently, the annual amount of the grant totaled $8 million. [80] Second, a Manure Management Planner (MMP) software program has been developed by Purdue University in conjunction with funding by a federal grant. The MMP is tailored to each state's technical standards (including Phosphorus Indexes and other assessment tools). [80] The MMP program provides free assistance to both permitting authorities and CAFO operators and can be found at the Purdue University website. [112] Lastly, the EPA notes that the USDA offers a "range of support services," including a long-term program that aims to assist CAFOs with NMPs. [80]
Environmentalists argue that the standards under the CWA are not strong enough. Researchers have identified regions in the country that have weak enforcement of regulations and, therefore, are popular locations for CAFO developers looking to reduce cost and expand operations without strict government oversight. [113] Even when laws are enforced, there is the risk of environmental accidents. The massive 1995 manure spill in North Carolina highlights the reality that contamination can happen even when it is not done maliciously. [114] The question of whether such a spill could have been avoided is a contributing factor in the debate for policy reform.
Environmental groups have criticized the EPA's regulation of CAFOs on several specific grounds, including the following. [115]
Conversely, industry groups criticize the EPA's rules as overly stringent. Industry groups vocally opposed the requirement in the 2008 rule (since struck down by the Fifth Circuit) that required CAFOs to seek a permit if they "propose to discharge" into waters of the United States. [120] Generally speaking, the farm industry disputes the presumption that CAFOs do discharge pollutants and it therefore objects to the pressure that the EPA places on CAFOs to voluntarily seek an NPDES permit. [120] As a starting point, farm industry groups "emphasize that most farmers are diligent stewards of the environment, since they depend on natural resources of the land, water, and air for their livelihoods and they, too, directly experience adverse impacts on water and air quality." [121] Some of the agricultural industry groups continue to maintain that the EPA should have no authority to regulate any of the runoff from land application areas because they believe this constitutes a nonpoint source that is outside the scope of the CWA. [115] According to this viewpoint, voluntary programs adequately address any problems with excess manure. [115]
The role of the federal government in environmental issues is generally to set national guidelines and the state governments' role is to address specific issues. The framework of federal goals is as such that the responsibility to prevent, reduce, and eliminate pollution are the responsibility of the states. [122]
The management of water and air standards follows this authoritative structure. States that have been authorized by the EPA to directly issue permits under NPDES (also known as "NPDES states" [123] ) have received jurisdiction over CAFOs. As a result of this delegation of authority from the EPA, CAFO permitting procedures and standards may vary from state to state.
Specifically for water pollution, the federal government establishes federal standards for wastewater discharge and authorized states develop their own wastewater policies to fall in compliance. More specifically, what a state allows an individual CAFO to discharge must be as strict or stricter than the federal government's standard. [124] This protection includes all waterways, whether or not the water body can safely sustain aquatic life or house public recreational activities. Higher standards are upheld in some cases of pristine publicly owned waterways, such as parks. They keep higher standards in order to maintain the pristine nature of the environment for preservation and recreation. Exceptions are in place for lower water quality standards in certain waterways if it is deemed economically significant. [122] These policy patterns are significant when considering the role of state governments' in CAFO permitting.
Federal law requires CAFOs to obtain NPDES permits before wastewater may be discharged from the facility. The state agency responsible for approving permits for CAFOs in a given state is dependent on the authorization of that state. The permitting process is divided into two main methods based on a state's authorization status. As of 2018, EPA has authorized 47 states to issue NPDES permits. Although they have their own state-specific permitting standards, permitting requirements in authorized states must be at least as stringent as the federal standards. [87] : 13 In the remaining states and territories, an EPA regional office issues NPDES permits. [123]
A state's authority and the state's environmental regulatory framework will determine the permit process and the state offices involved. Below are two examples of states' permitting organization.
Arizona issues permits through a general permitting process. CAFOs must obtain both a general Arizona Pollutant Discharge Elimination System (AZPDES) Permit and a general Aquifer Protection Permit. [125] The Arizona state agency tasked with managing permitting is the Arizona Department of Environmental Quality (ADEQ).
For the Aquifer Protection Permit, CAFOs are automatically permitted if they comply with the state's BMP outlined in the relevant state rule, listed on the ADEQ's website. Their compliance is evaluated through agency CAFO Inspection Program's onsite inspections. If a facility is found to be unlawfully discharging, then the agency may issue warnings and, if necessary, file suit against the facility. For the AZPDES permit, CAFOs are required to submit a Notice of Intent to the ADEQ. In addition, they must complete and submit a Nutrient Management Plan (NMP) for the state's annual report. [125]
Even in an authorized state, the EPA maintains oversight of state permitting programs. This would be most likely to happen in the event that a complaint is filed with the EPA by a third party. For instance, in 2008, Illinois Citizens for Clean Air & Water filed a complaint with the EPA arguing that the state was not properly implementing its CAFO permitting program. The EPA responded with an "informal" investigation. In a report released in 2010, the agency sided with the environmental organization and provided a list of recommendations and required action for the state to meet.
In unauthorized states, the EPA has the authority for issuing NPDES permits. In these states, such as Massachusetts, CAFOs communicate and file required documentation through an EPA regional office. In Massachusetts, the EPA issues a general permit for the entire state. The state's Department of Agricultural Resources (MDAR) has an agreement with the EPA for the implementation of CAFO rules. MDAR's major responsibility is educational. The agency assists operators in determining if their facility qualifies as a CAFO. Specifically they do onsite evaluations of facilities, provide advice on best practices, and provide information and technical assistance. [126]
If a state has additional state specific rules for water quality standards, the state government maintains the authority for permitting. For instance, New Mexico, also an unauthorized state, requires CAFOs and AFOs to obtain a Groundwater Permit if the facilities discharge waste in a manner that might affect local groundwater. The EPA is not involved in the issuing of this state permit. [126] Massachusetts, however, does not have additional state permit requirements. [126]
State planning laws and local zoning ordinances represent the main policy tools for regulating land use. Many states have passed legislation that specifically exempt CAFOs (and other agricultural entities) from zoning regulations. [127] The promulgation of so-called "right to farm" statutes have provided, in some instances, a shield from liability for CAFOs (and other potential nuisances in agricultural). [127] More specifically, the right-to-farm statutes seek to "limit the circumstances under which agricultural operations can be deemed nuisances."
The history of these agricultural exemptions dates back to the 1950s. Right-to-farm statutes expanded in the 1970s when state legislatures became increasingly sensitive to the loss of rural farmland to urban expansion. [128] The statutes were enacted at a time when CAFOs and "modern confinement operations did not factor into legislator's perceptions of the beneficiaries of [the] generosity" of such statutes. [127] Forty-three (43) states now have some sort of statutory protection for farmers from nuisance. Some of these states (such as Iowa, Oklahoma, Wyoming, Tennessee, and Kansas) also provide specific protection to animal feeding operations (AFOs) and CAFOs. [128] Right-to-farm statutes vary in form. Some states, for instance, require agricultural operation be located "within an acknowledged and approved agricultural district" in order to receive protection; other states do not. [128]
Opponents of CAFOs have challenged right-to-farm statutes in court, and the constitutionality of such statutes is not entirely clear. The Iowa Supreme Court, for instance, in 1998 struck down a right-to-farm statute as a "taking" (in violation of the 5th and 14th Amendments of the U.S. Constitution) because the statute stripped neighboring landowners of property rights without compensation. [129]
As of February 2023, 85 Iowa counties, the majority of Iowa counties, had passed a "Construction Evaluation Resolution"; [130] pursuant to Iowa Code section 459 only counties which have adopted such a "construction evaluation resolution" can submit to the Iowa Department of Natural Resources a recommendation to approve or disapprove a construction permit application regarding a proposed confinement feeding operation which the board of supervisors received between February 1, 2023, and January 31, 2024.
CAFOs are potentially subject to regulation under the Clean Air Act (CAA), but the emissions from CAFOs generally do not exceed established statutory thresholds. [131] In addition, the EPA's regulations do not provide a clear methodology for measuring emissions from CAFOs, which has "vexed both regulators and the industry." [132] Negotiations between the EPA and the agricultural industry did, however, result in an Air Compliance Agreement in January 2005. [131] [ dead link ] According to the agreement, certain animal feeding operations (AFOs) received a covenant not to sue from the EPA in exchange for payment of a civil penalty for past violations of the CAA and an agreement to allow their facilities to be monitored for a study on air pollution emissions in the agricultural sector. [131] [ dead link ] Results and analysis of the EPA's study are scheduled to be released later in 2011. [131] [ dead link ]
Environmental groups have formally proposed to tighten EPA regulation of air pollution from CAFOs. A coalition of environmental groups petitioned the EPA on April 6, 2011, to designate ammonia as a "criteria pollutant" and establish National Ambient Air Quality Standards (NAAQS) for ammonia from CAFOs. [131] [ dead link ] The petition alleges that "CAFOs are leading contributors to the nation's ammonia inventory; by one EPA estimate livestock account for approximately 80 percent of total emissions. CAFOs also emit a disproportionately large share of the ammonia in certain states and communities." [133] If the EPA adopts the petition, CAFOs and other sources of ammonia would be subject to the permitting requirements of the CAA.
Stormwater, also written storm water, is water that originates from precipitation (storm), including heavy rain and meltwater from hail and snow. Stormwater can soak into the soil (infiltrate) and become groundwater, be stored on depressed land surface in ponds and puddles, evaporate back into the atmosphere, or contribute to surface runoff. Most runoff is conveyed directly as surface water to nearby streams, rivers or other large water bodies without treatment.
The Clean Water Act (CWA) is the primary federal law in the United States governing water pollution. Its objective is to restore and maintain the chemical, physical, and biological integrity of the nation's waters; recognizing the responsibilities of the states in addressing pollution and providing assistance to states to do so, including funding for publicly owned treatment works for the improvement of wastewater treatment; and maintaining the integrity of wetlands.
Sewage disposal regulation and administration describes the governance of sewage treatment and disposal.
Agricultural wastewater treatment is a farm management agenda for controlling pollution from confined animal operations and from surface runoff that may be contaminated by chemicals in fertilizer, pesticides, animal slurry, crop residues or irrigation water. Agricultural wastewater treatment is required for continuous confined animal operations like milk and egg production. It may be performed in plants using mechanized treatment units similar to those used for industrial wastewater. Where land is available for ponds, settling basins and facultative lagoons may have lower operational costs for seasonal use conditions from breeding or harvest cycles. Animal slurries are usually treated by containment in anaerobic lagoons before disposal by spray or trickle application to grassland. Constructed wetlands are sometimes used to facilitate treatment of animal wastes.
New Source Performance Standards (NSPS) are pollution control standards issued by the United States Environmental Protection Agency (EPA). The term is used in the Clean Air Act Extension of 1970 (CAA) to refer to air pollution emission standards, and in the Clean Water Act (CWA) referring to standards for water pollution discharges of industrial wastewater to surface waters.
An anaerobic lagoon or manure lagoon is a man-made outdoor earthen basin filled with animal waste that undergoes anaerobic respiration as part of a system designed to manage and treat refuse created by concentrated animal feeding operations (CAFOs). Anaerobic lagoons are created from a manure slurry, which is washed out from underneath the animal pens and then piped into the lagoon. Sometimes the slurry is placed in an intermediate holding tank under or next to the barns before it is deposited in a lagoon. Once in the lagoon, the manure settles into two layers: a solid or sludge layer and a liquid layer. The manure then undergoes the process of anaerobic respiration, whereby the volatile organic compounds are converted into carbon dioxide and methane. Anaerobic lagoons are usually used to pretreat high strength industrial wastewaters and municipal wastewaters. This allows for preliminary sedimentation of suspended solids as a pretreatment process.
Effluent Guidelines are U.S. national standards for wastewater discharges to surface waters and publicly owned treatment works (POTW). The United States Environmental Protection Agency (EPA) issues Effluent Guideline regulations for categories of industrial sources of water pollution under Title III of the Clean Water Act (CWA). The standards are technology-based, i.e. they are based on the performance of treatment and control technologies. Effluent Guidelines are not based on risk or impacts of pollutants upon receiving waters.
Intensive animal farming, industrial livestock production, and macro-farms, also known as factory farming, is a type of intensive agriculture, specifically an approach to animal husbandry designed to maximize production while minimizing costs. To achieve this, agribusinesses keep livestock such as cattle, poultry, and fish at high stocking densities, at large scale, and using modern machinery, biotechnology, and global trade. The main products of this industry are meat, milk and eggs for human consumption.
Title 40 is a part of the United States Code of Federal Regulations. Title 40 arranges mainly environmental regulations that were promulgated by the US Environmental Protection Agency (EPA), based on the provisions of United States laws. Parts of the regulation may be updated annually on July 1.
A Discharge Monitoring Report (DMR) is a United States regulatory term for a periodic water pollution report prepared by industries, municipalities and other facilities discharging to surface waters. The facilities collect wastewater samples, conduct chemical and/or biological tests of the samples, and submit reports to a state agency or the United States Environmental Protection Agency (EPA). All point source dischargers to ”Waters of the U.S.” must obtain a National Pollution Discharge Elimination System (NPDES) permit from the appropriate agency, and many permittees are required to file DMRs.
The United States Environmental Protection Agency (EPA) defines an animal feeding operation (AFO) in the Code of Federal Regulations as a lot or facility where the following conditions are met:
Nutrient pollution, a form of water pollution, refers to contamination by excessive inputs of nutrients. It is a primary cause of eutrophication of surface waters, in which excess nutrients, usually nitrogen or phosphorus, stimulate algal growth. Sources of nutrient pollution include surface runoff from farm fields and pastures, discharges from septic tanks and feedlots, and emissions from combustion. Raw sewage is a large contributor to cultural eutrophication since sewage is high in nutrients. Releasing raw sewage into a large water body is referred to as sewage dumping, and still occurs all over the world. Excess reactive nitrogen compounds in the environment are associated with many large-scale environmental concerns. These include eutrophication of surface waters, harmful algal blooms, hypoxia, acid rain, nitrogen saturation in forests, and climate change.
Water quality laws govern the protection of water resources for human health and the environment. Water quality laws are legal standards or requirements governing water quality, that is, the concentrations of water pollutants in some regulated volume of water. Such standards are generally expressed as levels of a specific water pollutants that are deemed acceptable in the water volume, and are generally designed relative to the water's intended use - whether for human consumption, industrial or domestic use, recreation, or as aquatic habitat. Additionally, these laws provide regulations on the alteration of the chemical, physical, radiological, and biological characteristics of water resources. Regulatory efforts may include identifying and categorizing water pollutants, dictating acceptable pollutant concentrations in water resources, and limiting pollutant discharges from effluent sources. Regulatory areas include sewage treatment and disposal, industrial and agricultural waste water management, and control of surface runoff from construction sites and urban environments. Water quality laws provides the foundation for regulations in water standards, monitoring, required inspections and permits, and enforcement. These laws may be modified to meet current needs and priorities.
Water pollution in the United States is a growing problem that became critical in the 19th century with the development of mechanized agriculture, mining, and manufacturing industries—although laws and regulations introduced in the late 20th century have improved water quality in many water bodies. Extensive industrialization and rapid urban growth exacerbated water pollution as a lack of regulation allowed for discharges of sewage, toxic chemicals, nutrients, and other pollutants into surface water. This has led to the need for more improvement in water quality as it is still threatened and not fully safe.
Nonpoint source (NPS) water pollution regulations are environmental regulations that restrict or limit water pollution from diffuse or nonpoint effluent sources such as polluted runoff from agricultural areas in a river catchments or wind-borne debris blowing out to sea. In the United States, governments have taken a number of legal and regulatory approaches to controlling NPS effluent. Nonpoint water pollution sources include, for example, leakage from underground storage tanks, storm water runoff, atmospheric deposition of contaminants, and golf course, agricultural, and forestry runoff.
Point source water pollution comes from discrete conveyances and alters the chemical, biological, and physical characteristics of water. In the United States, it is largely regulated by the Clean Water Act (CWA). Among other things, the Act requires dischargers to obtain a National Pollutant Discharge Elimination System (NPDES) permit to legally discharge pollutants into a water body. However, point source pollution remains an issue in some water bodies, due to some limitations of the Act. Consequently, other regulatory approaches have emerged, such as water quality trading and voluntary community-level efforts.
Water in Arkansas is an important issue encompassing the conservation, protection, management, distribution and use of the water resource in the state. Arkansas contains a mixture of groundwater and surface water, with a variety of state and federal agencies responsible for the regulation of the water resource. In accordance with agency rules, state, and federal law, the state's water treatment facilities utilize engineering, chemistry, science and technology to treat raw water from the environment to potable water standards and distribute it through water mains to homes, farms, business and industrial customers. Following use, wastewater is collected in collection and conveyance systems, decentralized sewer systems or septic tanks and treated in accordance with regulations at publicly owned treatment works (POTWs) before being discharged to the environment.
The environmental impact of pig farming is mainly driven by the spread of feces and waste to surrounding neighborhoods, polluting air and water with toxic waste particles. Waste from pig farms can carry pathogens, bacteria, and heavy metals that can be toxic when ingested. Pig waste also contributes to groundwater pollution in the forms of groundwater seepage and waste spray into neighboring areas with sprinklers. The contents in the spray and waste drift have been shown to cause mucosal irritation, respiratory ailment, increased stress, decreased quality of life, and higher blood pressure. This form of waste disposal is an attempt for factory farms to be cost efficient. The environmental degradation resulting from pig farming presents an environmental injustice problem, since the communities do not receive any benefit from the operations, and instead, suffer negative externalities, such as pollution and health problems. The United States Agriculture and Consumer Health Department has stated that the "main direct environmental impact of pig production is related to the manure produced.
Groundwater pollution, also referred to as groundwater contamination, is not as easily classified as surface water pollution. Groundwater aquifers are susceptible to contamination from sources that may not directly affect surface water bodies.
County of Maui v. Hawaii Wildlife Fund, No. 18-260, 590 U.S. ___ (2020), was a United States Supreme Court case involving pollution discharges under the Clean Water Act (CWA). The case asked whether the Clean Water Act requires a permit when pollutants that originate from a non-point source can be traced to reach navigable waters through mechanisms such as groundwater transport. In a 6–3 decision, the Court ruled that such non-point discharges require a permit when they are the "functional equivalent of a direct discharge", a new test defined by the ruling. The decision vacated the ruling of the United States Court of Appeals for the Ninth Circuit, and remanded the case with instructions to apply the new standard to the lower courts with cooperation of the Environmental Protection Agency (EPA).