Combined Sewer Overflow in Nashville: Difference between revisions

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Combined Sewer Overflow (CSO) in Nashville refers to the environmental and public health challenge posed by the city's integrated wastewater and stormwater system, which can discharge untreated sewage and stormwater into waterways during heavy precipitation events. Nashville's combined sewer system, which serves portions of the metropolitan area, was constructed in the late 19th and early 20th centuries when separate storm and sanitary sewer infrastructure was not yet standard practice. When rainfall exceeds the capacity of treatment facilities, the system is designed to overflow directly into nearby waterways including the Cumberland River, Mill Creek, and other tributaries. This practice, while historical in origin, has become a significant environmental and regulatory concern in the 21st century, affecting water quality, public health, and the city's compliance with federal Clean Water Act requirements. The Nashville Metropolitan Government and the Metropolitan Water Services authority have undertaken comprehensive planning and infrastructure investments to address CSO issues as part of broader urban water management and sustainability initiatives.
```mediawiki
Combined Sewer Overflow (CSO) in Nashville refers to the environmental and public health challenge posed by the city's integrated wastewater and stormwater system, which can discharge untreated sewage and stormwater into waterways during heavy precipitation events. Nashville's combined sewer system, which serves portions of the metropolitan area, was constructed in the late 19th and early 20th centuries when separate storm and sanitary sewer infrastructure was not yet standard practice. When rainfall exceeds the capacity of treatment facilities, the system is designed to overflow directly into nearby waterways including the Cumberland River, Mill Creek, and other tributaries. This practice, while historical in origin, has become a significant environmental and regulatory concern subject to increasing federal and state scrutiny since the EPA's 1994 Combined Sewer Overflow Control Policy, affecting water quality, public health, and the city's compliance with federal Clean Water Act requirements.<ref>{{cite web |title=Combined Sewer Overflow Control Policy |url=https://www.epa.gov/npdes/combined-sewer-overflow-cso-control-policy |work=U.S. Environmental Protection Agency |access-date=2026-02-26}}</ref>
 
Metro Water Services (MWS) and the Metropolitan Government have undertaken comprehensive planning and infrastructure investments to address CSO issues as part of broader urban water management initiatives. Metro Water Services has renewed more than 200 miles of sewer pipe and over 5,300 manholes under the Clean Water Nashville program, with documented reductions in overflow events entering the Cumberland River.<ref>{{cite web |title=Renewing Nashville, One Sewer Pipe at a Time |url=https://www.cdmsmith.com/projects/clean-water-nashville-program |work=CDM Smith |access-date=2026-02-26}}</ref> Despite this progress, CSO events continue to occur during major storm events and winter ice storms, and regulators have emphasized that full compliance with permit obligations remains years away. Eyewitness accounts from affected Nashville neighborhoods have described raw sewage visibly surfacing in streets and yards during overflow events, with residents reporting the smell and presence of solid waste as unmistakable signs of system failure.<ref>{{cite web |title=You can smell it. There's toilet paper in it. There's solids coming out of it. |url=https://www.facebook.com/WSMVTV/posts/you-can-smell-it-theres-toilet-paper-in-it-theres-solids-coming-out-of-it-thats-/1482976060525533/ |work=WSMV 4 Nashville |access-date=2026-02-26}}</ref>


== History ==
== History ==


The origins of Nashville's combined sewer system trace to the late 1800s, when the city's infrastructure was rapidly expanding to accommodate growth following the Civil War. In that era, combined sewers—which carried both sanitary wastewater and stormwater in a single pipe—were considered an efficient engineering solution that minimized construction costs and land disruption. The Metropolitan Government's early sewer infrastructure, primarily constructed between 1880 and 1930, established this combined system throughout downtown Nashville and surrounding developed areas. As late 20th-century environmental regulations emerged, particularly following the passage of the federal Clean Water Act in 1972, the limitations and problems associated with combined sewers became increasingly apparent. The law and subsequent amendments created requirements for municipalities to control combined sewer overflows and improve water quality, establishing the regulatory framework within which Nashville has operated for decades.<ref>{{cite web |title=History of Nashville's Sewer Infrastructure |url=https://www.nashville.gov/water-services |work=Metropolitan Water Services |access-date=2026-02-26}}</ref>
Nashville's combined sewer system traces back to the late 1800s, when the city's infrastructure was rapidly expanding to accommodate growth following the Civil War. Combined sewers, which carried both sanitary wastewater and stormwater in a single pipe, seemed like an efficient engineering solution at the time, as they minimized construction costs and land disturbance. Most of the city's early sewer infrastructure was installed between 1880 and 1930, establishing this combined system throughout downtown Nashville and surrounding developed areas.
 
The federal Clean Water Act of 1972 (33 U.S.C. §1251 et seq.) introduced new requirements that would eventually reshape how cities managed their older sewer systems. As late 20th-century environmental regulations took hold, the limitations of combined sewers became increasingly apparent. The law and subsequent amendments created requirements for municipalities to control combined sewer overflows and improve water quality, establishing the regulatory framework within which Nashville has operated for decades.
 
During the 1980s and 1990s, Nashville conducted multiple combined sewer overflow studies and assessments required by federal environmental agencies. The U.S. Environmental Protection Agency (EPA) and the Tennessee Department of Environment and Conservation (TDEC) worked with the city to develop plans for addressing CSO issues. In 1994, Metro Water Services implemented its first comprehensive CSO Control Plan, which identified approximately 54 outfall locations where combined sewers discharged into the Cumberland River, Mill Creek, and other waterways. This document became foundational for long-term planning and established baseline conditions against which future improvements could be measured.
 
That same year, the EPA issued its national CSO Control Policy in the Federal Register (59 Fed. Reg. 18688, April 19, 1994). Nashville and hundreds of other cities were required to implement nine minimum controls immediately and to develop Long-Term Control Plans demonstrating compliance with Clean Water Act water quality standards.<ref>{{cite web |title=Combined Sewer Overflow (CSO) Control Policy |url=https://www.epa.gov/npdes/combined-sewer-overflow-cso-control-policy |work=U.S. Environmental Protection Agency |access-date=2026-02-26}}</ref>
 
Over subsequent decades, incremental improvements were made. Storage facilities were constructed, treatment plants were upgraded, and collection systems were modified. Nashville's combined sewer infrastructure covers approximately 380 miles of combined sewer pipes serving areas including downtown, East Nashville, and portions of South Nashville.<ref>{{cite web |title=Combined Sewer Overflow Long-Term Control Plan Update |url=https://www.nashville.gov/water-services/wastewater-services |work=Nashville Water Services |access-date=2026-02-26}}</ref> Complete elimination of overflows required sustained investment and infrastructure transformation spanning multiple decades.
 
In 2013, the Metropolitan Government signed an Agreed Order with TDEC that formalized a compliance schedule and required regular reporting milestones. This agreement established binding expectations for long-term planning and capital project implementation, with specific consequences for missed milestones. The 2020 Long-Term Control Plan Update, which superseded earlier planning documents, identified over $2 billion in capital projects necessary to significantly reduce CSO events over a 20-year period, setting out the most detailed compliance roadmap Nashville had yet committed to.<ref>{{cite web |title=Combined Sewer Overflow Long-Term Control Plan Update |url=https://www.nashville.gov/water-services/wastewater-services |work=Nashville Water Services |access-date=2026-02-26}}</ref>


Throughout the 1980s and 1990s, Nashville conducted multiple combined sewer overflow studies and assessments required by federal environmental agencies. The U.S. Environmental Protection Agency (EPA) and the Tennessee Department of Environment and Conservation (TDEC) worked with Nashville to develop plans for addressing CSO issues. In 1994, Metropolitan Water Services implemented its first comprehensive CSO Control Plan, which identified approximately 54 outfall locations where combined sewers discharged into the Cumberland River, Mill Creek, and other waterways. This document became foundational for long-term planning efforts and established baseline conditions against which future improvements could be measured. Over the subsequent decades, incremental improvements were made, including the construction of storage facilities, upgrades to treatment plants, and modifications to collection systems. However, the scale of Nashville's combined sewer infrastructure—covering approximately 380 miles of combined sewer pipes serving areas including downtown, East Nashville, and portions of South Nashville—meant that complete elimination of overflows would require sustained investment and infrastructure transformation.<ref>{{cite web |title=Combined Sewer Overflow Long-Term Control Plan Update |url=https://www.nashville.gov/water-services/wastewater-services |work=Nashville Water Services |access-date=2026-02-26}}</ref>
Nashville's Clean Water Nashville program became the primary vehicle for implementing sewer rehabilitation and renewal projects across the combined sewer service area. Developed in coordination with CDM Smith and other engineering contractors, the program has made measurable progress. By the mid-2020s, it had renewed more than 200 miles of deteriorating sewer pipe and rehabilitated over 5,300 manholes, producing documented reductions in the volume of sewage overflowing into the Cumberland River and its tributaries during storm events.<ref>{{cite web |title=Renewing Nashville, One Sewer Pipe at a Time |url=https://www.cdmsmith.com/projects/clean-water-nashville-program |work=CDM Smith |access-date=2026-02-26}}</ref> These outcomes represent a concrete shift from the baseline conditions documented in the 1994 plan. Still, regulators and advocates have emphasized that significant work remains before Nashville achieves full compliance with its permit obligations.


== Geography ==
== Geography ==


Nashville's combined sewer system is concentrated in areas of the city that experienced urbanization before mid-20th century standards were established. The primary combined sewer service area encompasses much of downtown Nashville, portions of East Nashville along the Cumberland River, areas surrounding Mill Creek in South Nashville, and neighborhoods adjacent to Sulphur Fork Creek. The Cumberland River, which flows through the heart of Nashville and is the primary receiving waterway for most CSO events, has been the focus of particular environmental monitoring and management attention. CSO outfalls are distributed throughout this urban core, with the highest concentrations located near the confluence of Mill Creek and the Cumberland River, an area that has historically been subject to both urban runoff and sanitary sewer contributions during precipitation events. The topography of Nashville, with its rolling terrain and relatively high annual precipitation averaging 47 inches, creates conditions where stormwater management represents a persistent infrastructure challenge.
Nashville's combined sewer system is concentrated in areas of the city that experienced urbanization before mid-20th century standards were established. The primary service area encompasses much of downtown Nashville, portions of East Nashville along the Cumberland River, areas surrounding Mill Creek in South Nashville, and neighborhoods adjacent to Sulphur Fork Creek. The Cumberland River, which flows through the heart of Nashville, is the primary receiving waterway for most CSO events and has received particular environmental monitoring and management attention. CSO outfalls are distributed throughout this urban core, with the highest concentrations located near the confluence of Mill Creek and the Cumberland River, an area that has historically been subject to both urban runoff and sanitary sewer contributions during precipitation events.
 
Nashville's rolling terrain and relatively high annual precipitation averaging 47 inches create conditions where stormwater management is a persistent infrastructure challenge. During light to moderate rainfall events, the combined sewer system typically functions as designed, conveying flows to treatment plants. During significant precipitation events, commonly defined as those exceeding 0.5 inches in 24 hours, the system's capacity is exceeded and overflow mechanisms activate. The Cumberland River's receiving capacity, water quality characteristics, and ecological sensitivity have made it a focal point for CSO management efforts. Downstream communities, including areas along the Cumberland River in Cheatham and Robertson counties, can be affected by increased turbidity, bacterial loading, and elevated nutrient levels following CSO events in Nashville.
 
The geographic distribution of older infrastructure means that neighborhoods in East Nashville and downtown face the most direct exposure to CSO-related water quality degradation. These are predominantly lower-income and historically Black communities dealing with environmental justice concerns.<ref>{{cite web |title=Nashville CSO Outfall Locations and Monitoring Data |url=https://www.nashville.gov/water-services/environmental-quality |work=Metropolitan Water Services |access-date=2026-02-26}}</ref>
 
The EPA's 2004 Report to Congress on the Impacts and Control of CSOs and SSOs documented that this pattern is widespread. Older urban communities of color across the United States disproportionately bear the burden of combined sewer infrastructure that has not been upgraded at the same pace as wealthier neighborhoods.<ref>{{cite web |title=Report to Congress: Impacts and Control of CSOs and SSOs |url=https://www.epa.gov/npdes/report-congress-impacts-and-control-combined-sewer-overflows-and-sanitary-sewer-overflows |work=U.S. Environmental Protection Agency |year=2004 |access-date=2026-02-26}}</ref>
 
Nashville's CSO challenges exist within a broader Middle Tennessee context. Neighboring Williamson County has faced its own sewage infrastructure failures, including a long-running dispute over a failing sewage treatment plant that discharged into the Harpeth River. After more than twelve years of documented violations, residents have demanded regulatory action against a facility that leaked at least 20,000 gallons of sewage into the Harpeth River, prompting local ordinance changes and intensifying public scrutiny of regional wastewater management practices.<ref>{{cite web |title=These Tennesseans Demand Action on Failing Sewage Plant That Leaked 20K Gallons into Harpeth River |url=https://www.newschannel5.com/news/state/tennessee/williamson-county/these-tennesseans-demand-action-on-failing-sewage-plant-that-leaked-20k-gallons-into-harpeth-river |work=NewsChannel 5 Nashville |access-date=2026-02-26}}</ref> Lebanon, Tennessee, has similarly faced state scrutiny for repeated sewer violations tied to rapid growth, illustrating a pattern of aging and overburdened sewer infrastructure across the region.<ref>{{cite web |title=State records show repeated sewer violations in Lebanon, raising questions about growth |url=https://fox17.com/news/local/state-records-show-repeated-sewer-violations-in-lebanon-raising-questions-about-growth |work=WZTV FOX 17 |access-date=2026-02-26}}</ref> These regional incidents demonstrate that Nashville's CSO management efforts take place within a broader watershed context where multiple municipalities share responsibility for the health of interconnected waterways.
 
== Regulatory Framework and Compliance ==
 
Nashville's approach to combined sewer overflow management has been shaped by significant regulatory interactions with federal and state environmental agencies over more than three decades. The EPA's 1994 CSO Control Policy, published in the Federal Register at 59 Fed. Reg. 18688, established the national framework. It required municipalities to implement nine minimum controls immediately and to develop Long-Term Control Plans demonstrating compliance with the Clean Water Act's water quality standards.<ref>{{cite web |title=Combined Sewer Overflow (CSO) Control Policy |url=https://www.epa.gov/npdes/combined-sewer-overflow-cso-control-policy |work=U.S. Environmental Protection Agency |access-date=2026-02-26}}</ref>


The geographic extent of the problem varies seasonally and by precipitation intensity. During light to moderate rainfall events, the combined sewer system typically functions as designed, conveying flows to treatment plants. However, during significant precipitation events—commonly defined as those exceeding 0.5 inches in 24 hours—the system's capacity is exceeded and overflow mechanisms activate. The Cumberland River's receiving capacity, water quality characteristics, and ecological sensitivity have made it a focal point for CSO management efforts. Downstream communities, including areas along the Cumberland River in Cheatham and Robertson counties, can be affected by increased turbidity, bacterial loading, and nutrient levels following CSO events in Nashville. Additionally, the geographic distribution of older infrastructure means that neighborhoods in East Nashville and downtown, which are predominantly lower-income and historically Black communities, face the most direct exposure to CSO-related water quality degradation and associated environmental justice concerns.<ref>{{cite web |title=Nashville CSO Outfall Locations and Monitoring Data |url=https://www.nashville.gov/water-services/environmental-quality |work=Metropolitan Water Services |access-date=2026-02-26}}</ref>
Nashville operates under National Pollutant Discharge Elimination System (NPDES) permits administered jointly by the EPA Region 4 and TDEC, which set specific limits on the frequency and volume of permitted overflow events at each outfall location. In 2013, the Metropolitan Government signed an Agreed Order with TDEC regarding CSO compliance, establishing specific milestones and timelines for infrastructure improvements. This agreement formalized expectations for long-term planning and implementation while providing some flexibility in the schedule for capital projects, though missed milestones carry potential enforcement consequences under both state and federal law.


== Economy ==
TDEC and EPA oversight of Nashville's progress has included regular reporting requirements, environmental monitoring, and assessment of whether the city's management efforts are achieving measurable water quality improvements in the Cumberland River and its tributaries. These regulatory relationships have been largely collaborative, with technical assistance from state and federal agencies helping Nashville develop cost-effective solutions. Metro Water Services is required to notify the public when CSO events occur, and annual compliance reports are submitted to TDEC documenting overflow volumes, frequencies, and the status of capital improvement milestones.<ref>{{cite web |title=Tennessee Department of Environment and Conservation Division of Water Resources |url=https://www.tn.gov/environment/program-areas/wr-water-resources.html |work=Tennessee Department of Environment and Conservation |access-date=2026-02-26}}</ref>


The economic implications of combined sewer overflow management in Nashville extend across multiple sectors of the local economy and municipal budget. Metropolitan Water Services, which operates the city's water and wastewater systems, has allocated hundreds of millions of dollars toward CSO abatement infrastructure improvements. The 2020 Long-Term Control Plan Update identified over $2 billion in capital projects necessary to significantly reduce CSO events over a 20-year period, with costs distributed across rate-payers through water and wastewater utility charges. This substantial capital investment has economic effects on residential and commercial customers, as utility rates have increased to fund infrastructure improvements. Small businesses, particularly in areas with older combined sewer infrastructure such as downtown and East Nashville, may experience variable impacts depending on their water usage and stormwater management practices.
The 2020 Long-Term Control Plan Update represented Nashville's most comprehensive regulatory commitment to date. It lays out a 20-year roadmap for reducing overflow events to levels that protect water quality in the Cumberland River and its tributaries. Progress under this plan is tracked through annual reports submitted to TDEC, and Metro Water Services publishes monitoring data for each active outfall location as part of its public transparency obligations. Whether Nashville achieves the plan's targets on schedule will depend on sustained capital investment, continued construction of storage and conveyance infrastructure, and the effectiveness of green infrastructure programs in reducing the volume of stormwater entering the combined sewer system during storm events.<ref>{{cite web |title=Combined Sewer Overflow Long-Term Control Plan Update |url=https://www.nashville.gov/water-services/wastewater-services |work=Nashville Water Services |access-date=2026-02-26}}</ref>


The CSO challenge also affects Nashville's tourism and economic development sectors. Water quality concerns in the Cumberland River, while not prohibitive to recreation, have influenced public perception and may deter some swimming and water-based activities in areas downstream of significant CSO outfalls. However, water quality improvements resulting from CSO control investments have been identified as economic benefits that support downtown redevelopment, riverfront attractions, and public health. Local environmental organizations and advocates have argued that CSO control investments represent long-term economic benefits through improved public health, ecosystem restoration, and enhanced property values in waterfront areas. The intersection of CSO management with broader sustainability initiatives has created economic opportunities in green infrastructure, including permeable pavements, green roofs, and bioswales that reduce stormwater runoff. Contracts for CSO control project implementation have supported construction and engineering employment, though the total economic burden of compliance remains significant for the municipal budget and ratepayers.<ref>{{cite web |title=Water Utility Rates and CSO Control Program Funding |url=https://www.tennessean.com/water-quality-nashville |work=The Tennessean |access-date=2026-02-26}}</ref>
== Environmental and Public Health Impacts ==


== Notable Regulatory and Environmental Developments ==
The discharge of untreated or partially treated sewage into the Cumberland River and its tributaries during CSO events poses documented risks to both aquatic ecosystems and human health. Combined sewer overflows introduce elevated concentrations of fecal coliform bacteria, biochemical oxygen demand (BOD), nutrients including nitrogen and phosphorus, and suspended solids into receiving waterways. These pollutants can depress dissolved oxygen levels, harm aquatic macroinvertebrates and fish, and create conditions that make contact recreation unsafe for days following a significant overflow event.


Nashville's approach to combined sewer overflow management has been shaped by significant regulatory interactions with federal and state environmental agencies. In 2013, the Metropolitan Government signed an Agreed Order with the Tennessee Department of Environment and Conservation regarding CSO compliance, which established specific milestones and timelines for infrastructure improvements. This agreement formalized expectations for long-term planning and implementation while providing flexibility in the schedule for capital projects. The TDEC and EPA's oversight of Nashville's progress has included regular reporting requirements, environmental monitoring, and assessment of whether the city's management efforts are achieving measurable water quality improvements. These regulatory relationships have been largely collaborative, with technical assistance provided by state and federal agencies to support Nashville's development of cost-effective solutions.
The Cumberland River at Nashville is monitored for water quality parameters by both Metro Water Services and the U.S. Geological Survey, which operates gauging stations that provide continuous data on river conditions. Bacterial contamination levels following CSO events frequently exceed safe limits for body contact recreation as defined by EPA standards — 126 colony-forming units of E. coli per 100 milliliters for recreational waters. Residents and visitors are advised to avoid swimming and water contact in areas near known CSO outfalls during and for 48 to 72 hours following significant rainfall events.<ref>{{cite web |title=USGS Water Resources Data, Cumberland River at Nashville |url=https://waterdata.usgs.gov/nwis |work=U.S. Geological Survey |access-date=2026-02-26}}</ref>


Environmental advocacy organizations have played an important role in elevating awareness of CSO issues and maintaining public and political focus on implementation of control plans. Groups including the Tennessee Environmental Council and the Alive Riverway Partnership have documented CSO events, monitored water quality impacts, and engaged in public education regarding the environmental and health implications of overflows. Public health departments have conducted investigation of waterborne illness reports and beach closure recommendations related to water quality degradation following CSO events. These multiple stakeholder groups have collectively contributed to the framing of CSO management as a priority environmental issue in Nashville, supporting municipal investment in infrastructure improvements and alternative management approaches. Citizen science initiatives, including volunteer water quality monitoring and community engagement in green infrastructure installation, have created opportunities for public participation in addressing CSO challenges.
Mill Creek, which receives CSO discharges from South Nashville outfalls before joining the Cumberland River, has historically exhibited particularly elevated bacterial and nutrient levels tied to combined sewer contributions. The creek flows through densely populated urban neighborhoods and has limited capacity to dilute overflow volumes during wet weather. Downstream of the Mill Creek confluence, the Cumberland River can show measurably elevated turbidity and bacterial loads that persist until flows recede and natural dilution takes effect.


{{#seo: |title=Combined Sewer Overflow in Nashville | Nashville.Wiki |description=Combined Sewer Overflow in Nashville represents wastewater system discharge into waterways during heavy rain, posing environmental and public health challenges requiring billions in infrastructure investment. |type=Article }}
Beyond waterway impacts, CSO events create direct public health hazards in affected neighborhoods when overflows surface through manholes, catch basins, or low-lying yards during extreme rainfall. Residents in East Nashville and downtown have reported visible sewage surfacing in streets during major storm events, with the characteristic odor and solid waste content making the health risk immediately apparent.<ref>{{cite web |title=You can smell it. There's toilet paper in it. There's solids coming out of it. |url=https://www.facebook.com/WSMVTV/posts/you-can-smell-it-theres-toilet-paper-in-it-theres-solids-coming-out-of-it-thats-/1482976060525533/ |work=WSMV 4 Nashville |access-date=2026-02-26}}</ref> These surface overflows, sometimes called "sanitary sewer overflows" when they occur from manhole surcharging rather than designated outfalls, expose residents to pathogens including E. coli, Cryptosporidium, and Giardia, particularly concerning for children and immunocompromised individuals.


[[Category:Nashville landmarks]]
Long-term exposure to CSO-impaired waterways has broader public health implications for communities that rely on the Cumberland River for recreation, subsistence fishing, or simply proximity to waterfront green space. Environmental justice advocates have noted that the
[[Category:Nashville history]]

Latest revision as of 03:11, 7 June 2026

```mediawiki Combined Sewer Overflow (CSO) in Nashville refers to the environmental and public health challenge posed by the city's integrated wastewater and stormwater system, which can discharge untreated sewage and stormwater into waterways during heavy precipitation events. Nashville's combined sewer system, which serves portions of the metropolitan area, was constructed in the late 19th and early 20th centuries when separate storm and sanitary sewer infrastructure was not yet standard practice. When rainfall exceeds the capacity of treatment facilities, the system is designed to overflow directly into nearby waterways including the Cumberland River, Mill Creek, and other tributaries. This practice, while historical in origin, has become a significant environmental and regulatory concern subject to increasing federal and state scrutiny since the EPA's 1994 Combined Sewer Overflow Control Policy, affecting water quality, public health, and the city's compliance with federal Clean Water Act requirements.[1]

Metro Water Services (MWS) and the Metropolitan Government have undertaken comprehensive planning and infrastructure investments to address CSO issues as part of broader urban water management initiatives. Metro Water Services has renewed more than 200 miles of sewer pipe and over 5,300 manholes under the Clean Water Nashville program, with documented reductions in overflow events entering the Cumberland River.[2] Despite this progress, CSO events continue to occur during major storm events and winter ice storms, and regulators have emphasized that full compliance with permit obligations remains years away. Eyewitness accounts from affected Nashville neighborhoods have described raw sewage visibly surfacing in streets and yards during overflow events, with residents reporting the smell and presence of solid waste as unmistakable signs of system failure.[3]

History

Nashville's combined sewer system traces back to the late 1800s, when the city's infrastructure was rapidly expanding to accommodate growth following the Civil War. Combined sewers, which carried both sanitary wastewater and stormwater in a single pipe, seemed like an efficient engineering solution at the time, as they minimized construction costs and land disturbance. Most of the city's early sewer infrastructure was installed between 1880 and 1930, establishing this combined system throughout downtown Nashville and surrounding developed areas.

The federal Clean Water Act of 1972 (33 U.S.C. §1251 et seq.) introduced new requirements that would eventually reshape how cities managed their older sewer systems. As late 20th-century environmental regulations took hold, the limitations of combined sewers became increasingly apparent. The law and subsequent amendments created requirements for municipalities to control combined sewer overflows and improve water quality, establishing the regulatory framework within which Nashville has operated for decades.

During the 1980s and 1990s, Nashville conducted multiple combined sewer overflow studies and assessments required by federal environmental agencies. The U.S. Environmental Protection Agency (EPA) and the Tennessee Department of Environment and Conservation (TDEC) worked with the city to develop plans for addressing CSO issues. In 1994, Metro Water Services implemented its first comprehensive CSO Control Plan, which identified approximately 54 outfall locations where combined sewers discharged into the Cumberland River, Mill Creek, and other waterways. This document became foundational for long-term planning and established baseline conditions against which future improvements could be measured.

That same year, the EPA issued its national CSO Control Policy in the Federal Register (59 Fed. Reg. 18688, April 19, 1994). Nashville and hundreds of other cities were required to implement nine minimum controls immediately and to develop Long-Term Control Plans demonstrating compliance with Clean Water Act water quality standards.[4]

Over subsequent decades, incremental improvements were made. Storage facilities were constructed, treatment plants were upgraded, and collection systems were modified. Nashville's combined sewer infrastructure covers approximately 380 miles of combined sewer pipes serving areas including downtown, East Nashville, and portions of South Nashville.[5] Complete elimination of overflows required sustained investment and infrastructure transformation spanning multiple decades.

In 2013, the Metropolitan Government signed an Agreed Order with TDEC that formalized a compliance schedule and required regular reporting milestones. This agreement established binding expectations for long-term planning and capital project implementation, with specific consequences for missed milestones. The 2020 Long-Term Control Plan Update, which superseded earlier planning documents, identified over $2 billion in capital projects necessary to significantly reduce CSO events over a 20-year period, setting out the most detailed compliance roadmap Nashville had yet committed to.[6]

Nashville's Clean Water Nashville program became the primary vehicle for implementing sewer rehabilitation and renewal projects across the combined sewer service area. Developed in coordination with CDM Smith and other engineering contractors, the program has made measurable progress. By the mid-2020s, it had renewed more than 200 miles of deteriorating sewer pipe and rehabilitated over 5,300 manholes, producing documented reductions in the volume of sewage overflowing into the Cumberland River and its tributaries during storm events.[7] These outcomes represent a concrete shift from the baseline conditions documented in the 1994 plan. Still, regulators and advocates have emphasized that significant work remains before Nashville achieves full compliance with its permit obligations.

Geography

Nashville's combined sewer system is concentrated in areas of the city that experienced urbanization before mid-20th century standards were established. The primary service area encompasses much of downtown Nashville, portions of East Nashville along the Cumberland River, areas surrounding Mill Creek in South Nashville, and neighborhoods adjacent to Sulphur Fork Creek. The Cumberland River, which flows through the heart of Nashville, is the primary receiving waterway for most CSO events and has received particular environmental monitoring and management attention. CSO outfalls are distributed throughout this urban core, with the highest concentrations located near the confluence of Mill Creek and the Cumberland River, an area that has historically been subject to both urban runoff and sanitary sewer contributions during precipitation events.

Nashville's rolling terrain and relatively high annual precipitation averaging 47 inches create conditions where stormwater management is a persistent infrastructure challenge. During light to moderate rainfall events, the combined sewer system typically functions as designed, conveying flows to treatment plants. During significant precipitation events, commonly defined as those exceeding 0.5 inches in 24 hours, the system's capacity is exceeded and overflow mechanisms activate. The Cumberland River's receiving capacity, water quality characteristics, and ecological sensitivity have made it a focal point for CSO management efforts. Downstream communities, including areas along the Cumberland River in Cheatham and Robertson counties, can be affected by increased turbidity, bacterial loading, and elevated nutrient levels following CSO events in Nashville.

The geographic distribution of older infrastructure means that neighborhoods in East Nashville and downtown face the most direct exposure to CSO-related water quality degradation. These are predominantly lower-income and historically Black communities dealing with environmental justice concerns.[8]

The EPA's 2004 Report to Congress on the Impacts and Control of CSOs and SSOs documented that this pattern is widespread. Older urban communities of color across the United States disproportionately bear the burden of combined sewer infrastructure that has not been upgraded at the same pace as wealthier neighborhoods.[9]

Nashville's CSO challenges exist within a broader Middle Tennessee context. Neighboring Williamson County has faced its own sewage infrastructure failures, including a long-running dispute over a failing sewage treatment plant that discharged into the Harpeth River. After more than twelve years of documented violations, residents have demanded regulatory action against a facility that leaked at least 20,000 gallons of sewage into the Harpeth River, prompting local ordinance changes and intensifying public scrutiny of regional wastewater management practices.[10] Lebanon, Tennessee, has similarly faced state scrutiny for repeated sewer violations tied to rapid growth, illustrating a pattern of aging and overburdened sewer infrastructure across the region.[11] These regional incidents demonstrate that Nashville's CSO management efforts take place within a broader watershed context where multiple municipalities share responsibility for the health of interconnected waterways.

Regulatory Framework and Compliance

Nashville's approach to combined sewer overflow management has been shaped by significant regulatory interactions with federal and state environmental agencies over more than three decades. The EPA's 1994 CSO Control Policy, published in the Federal Register at 59 Fed. Reg. 18688, established the national framework. It required municipalities to implement nine minimum controls immediately and to develop Long-Term Control Plans demonstrating compliance with the Clean Water Act's water quality standards.[12]

Nashville operates under National Pollutant Discharge Elimination System (NPDES) permits administered jointly by the EPA Region 4 and TDEC, which set specific limits on the frequency and volume of permitted overflow events at each outfall location. In 2013, the Metropolitan Government signed an Agreed Order with TDEC regarding CSO compliance, establishing specific milestones and timelines for infrastructure improvements. This agreement formalized expectations for long-term planning and implementation while providing some flexibility in the schedule for capital projects, though missed milestones carry potential enforcement consequences under both state and federal law.

TDEC and EPA oversight of Nashville's progress has included regular reporting requirements, environmental monitoring, and assessment of whether the city's management efforts are achieving measurable water quality improvements in the Cumberland River and its tributaries. These regulatory relationships have been largely collaborative, with technical assistance from state and federal agencies helping Nashville develop cost-effective solutions. Metro Water Services is required to notify the public when CSO events occur, and annual compliance reports are submitted to TDEC documenting overflow volumes, frequencies, and the status of capital improvement milestones.[13]

The 2020 Long-Term Control Plan Update represented Nashville's most comprehensive regulatory commitment to date. It lays out a 20-year roadmap for reducing overflow events to levels that protect water quality in the Cumberland River and its tributaries. Progress under this plan is tracked through annual reports submitted to TDEC, and Metro Water Services publishes monitoring data for each active outfall location as part of its public transparency obligations. Whether Nashville achieves the plan's targets on schedule will depend on sustained capital investment, continued construction of storage and conveyance infrastructure, and the effectiveness of green infrastructure programs in reducing the volume of stormwater entering the combined sewer system during storm events.[14]

Environmental and Public Health Impacts

The discharge of untreated or partially treated sewage into the Cumberland River and its tributaries during CSO events poses documented risks to both aquatic ecosystems and human health. Combined sewer overflows introduce elevated concentrations of fecal coliform bacteria, biochemical oxygen demand (BOD), nutrients including nitrogen and phosphorus, and suspended solids into receiving waterways. These pollutants can depress dissolved oxygen levels, harm aquatic macroinvertebrates and fish, and create conditions that make contact recreation unsafe for days following a significant overflow event.

The Cumberland River at Nashville is monitored for water quality parameters by both Metro Water Services and the U.S. Geological Survey, which operates gauging stations that provide continuous data on river conditions. Bacterial contamination levels following CSO events frequently exceed safe limits for body contact recreation as defined by EPA standards — 126 colony-forming units of E. coli per 100 milliliters for recreational waters. Residents and visitors are advised to avoid swimming and water contact in areas near known CSO outfalls during and for 48 to 72 hours following significant rainfall events.[15]

Mill Creek, which receives CSO discharges from South Nashville outfalls before joining the Cumberland River, has historically exhibited particularly elevated bacterial and nutrient levels tied to combined sewer contributions. The creek flows through densely populated urban neighborhoods and has limited capacity to dilute overflow volumes during wet weather. Downstream of the Mill Creek confluence, the Cumberland River can show measurably elevated turbidity and bacterial loads that persist until flows recede and natural dilution takes effect.

Beyond waterway impacts, CSO events create direct public health hazards in affected neighborhoods when overflows surface through manholes, catch basins, or low-lying yards during extreme rainfall. Residents in East Nashville and downtown have reported visible sewage surfacing in streets during major storm events, with the characteristic odor and solid waste content making the health risk immediately apparent.[16] These surface overflows, sometimes called "sanitary sewer overflows" when they occur from manhole surcharging rather than designated outfalls, expose residents to pathogens including E. coli, Cryptosporidium, and Giardia, particularly concerning for children and immunocompromised individuals.

Long-term exposure to CSO-impaired waterways has broader public health implications for communities that rely on the Cumberland River for recreation, subsistence fishing, or simply proximity to waterfront green space. Environmental justice advocates have noted that the