2. Background

Drinking water quality can be critical to public health. Congress passed the Safe Drinking Water Act (SDWA) in 1974 and amendments in 1986 and 1996 to protect the nation's public drinking water supply. Under the SDWA, the U.S. EPA promulgated National Primary Drinking Water Regulations (NPDWR) (U.S. Government Publishing Office 2019) to set standards and treatment techniques for more than 90 contaminants (Tiemann Reference Tiemann2017). The NPDWR applies to over 170,000 public water systems (PWSs) that are identified as having at least 15 service connections or serving at least 25 people per day for 60 days of the year (Office of Water, U.S. EPA 2004). EPA usually authorizes states and Indian tribes to assume primary oversight for PWSs to enforce NPDWR. PWSs should monitor regulated contaminants in their water supply and report monitoring results to their primacy agencies in order to be determined as in compliance under NPDWR (Tiemann Reference Tiemann2017). PWSs’ violations may lead to enforcement actions such as administrative orders, financial penalties, and civil actions against PWSs.

Despite established regulations, improper disposal of chemicals, animal wastes, pesticides, fertilizers, wastes injected to groundwater, and naturally occurring substances can all contaminate drinking water (Office of Water, U.S. EPA 2004). For example, the natural occurrence of a moderate to a high level of arsenic in groundwater is common in western states (Welch, Lico, and Hughes Reference Welch, Lico and Hughes1988). EPA's National Water Quality Inventory (2017) reports that 46 percent of river and stream miles are in poor biological condition and 21 percent of the nation's lakes are hypereutrophic (i.e., with the highest levels of nutrients, algae, and plants), where phosphorus and nitrogen are the most widespread stressors in rivers and lakes. Moreover, enforcement failure, improper treatment, and poorly maintained distribution systems can adversely affect drinking water quality (Office of Water, EPA 2004). The Flint water crisis is a result of improper treatment and failures at multiple levels of government (Butler, Scammell, and Benson Reference Butler, Scammell and Benson2016). The lead crisis in Washington, DC, in 2001 is a result of the reaction between old lead pipes and new treatment chemicals applied by the plant to comply with the Disinfection Byproducts Rule (Renner Reference Renner2004). Compliance issues also persist and may negatively impact drinking water quality. The U.S. EPA Office of Enforcement and Compliance Assurance (2013) national public water systems compliance report finds that MR violation is the dominant violation type, indicating a large number of PWSs fail to meet monitoring and reporting frequency rules for the drinking water quality during applicable compliance periods.

Small PWSs are more likely to violate NPDWRs, due to a lack of resources to conduct proper operation and maintenance. The U.S. EPA Office of Enforcement and Compliance Assurance (2013) national public water systems compliance report suggests that noncompliance occurs more frequently in small PWSs, despite EPA's and states’ efforts to develop financial and operational programs to assist small PWSs to achieve better compliance. Rubin (Reference Rubin2013) reports summary statistics based on the U.S. EPA data for violations by community water systems (CWSs). Results show that small water systems are more likely to violate health-related requirements than large systems. Guerrero-Preston et al. (Reference Guerrero-Preston, Norat, Rodríguez, Santiago and Suárez2008) use a small sample of CWSs over a five-year period to identify non-compliance with drinking water standards in Puerto Rico. They found that most small rural systems in Puerto Rico were noncompliant with NPDWRs during the study period.

PWSs serving low-income and minority communities are more likely to violate NPDWRs. Balazs et al. (Reference Balazs, Morello-Frosch, Hubbard and Ray2011) combine water quality monitoring datasets (1999–2001), source location, and census block group data in California to study the relationship between CWSs’ nitrate levels and socioeconomic status of the population served. They find that in smaller water systems, CWSs serving larger percentages of Latinos and renters receive drinking water with higher nitrate levels. Balazs et al. (Reference Balazs, Morello-Frosch, Hubbard and Ray2012) find similar conclusions in terms of arsenic MCL violations in the same study area. Pilley et al. (Reference Pilley, Jacquez, Buckingham, Rao, Sapkota, Rai, Graboski-Bauer and Reddy2009) evaluate the applicability of the Promotora Model in Dona Ana County in New Mexico, where arsenic levels in southern New Mexico are significantly higher than EPA-designated MCL. The Environmental Justice Coalition for Water (2005) reports that counties with a high Latino population have more drinking water violations in California.

Monitoring requirements and violation determinations are different among contaminants under SDWA and NPDWR (U.S. Government Publishing Office 2019). For inorganic chemicals such as arsenic, annual samples must be taken for surface water PWSs and triennial samples must be taken for groundwater PWSs. A PWS is in violation if the sampled contaminant exceeds the MCL standard set by EPA. PWSs with MCL violations must increase monitoring or sampling frequency to quarterly, and the violation is determined based on the annual average of all quarterly samples. For total coliform, the number of required routine samples are based on population served and must be taken at regular intervals each month at representative sites across every PWS. If a routine sample is total coliform positive, a PWS must take and analyze one repeat sample at the same tap as the original sample, and at a location within five connections both upstream and downstream within one day.

Violations are also dependent on the sampling frequency. A PWS taking fewer than 40 samples per month is in violation if two or more of their routine and repeat samples per month are total coliform-positive. A PWS taking more than 40 samples per month is in violation if more than five percent of routine and repeat samples per month are total coliform-positive. Stage one disinfection byproductsFootnote ³ are mostly monitored quarterly, and the MCL violation is based on the running annual average of all quarterly samples. For most of the contaminants, failure to monitor, failure to monitor at a specified frequency, and failure to report the testing measurement on time are regarded as MR violations by the state and the EPA.

In lieu of an MCL, NPDWR specifies treatment techniques for specific biological pathogens (giardia lamblia, viruses, heterotrophic plate count bacteria, Legionella) and turbidity. Filtration and disinfection are required to be installed and properly operated to reliably achieve at least 99.9 percent removal or inactivation of Giardia lamblia, 99.99 percent removal or inactivation of viruses, fecal coliform concentration no greater than 20/100 ml, and turbidity level no greater 5 NTU.Footnote ⁴ Failure to properly install filtration and disinfection or failure to achieve the above substance level will result in a treatment technique violation. NPDWR also specifies treatment techniques for lead and copper instead of an MCL. Small (serving <3,300 persons) and medium systems (serving 3,300–50,000 persons) with lead and copper action level exceedance and all large PWSs shall install the optimal corrosion control treatment steps within the specified time frame or they are in violation of treatment techniques regulations.

All PWSs already applying optimizing corrosion control treatment shall monitor water quality parameters designated by the state and will be in treatment technique (TT) violations if they have an deviation for any parameters on more than nine days during each six-month monitoring period. EPA specifies treatment techniques for certain contaminants that have MCL designations, such as total organic carbon (TOC) in stage 1 Disinfectants and Disinfection Byproducts (DBP). NPDWR requires PWSs using conventional filtration treatment to remove specific percentages of TOC that may react with disinfectants to form DBPs. Removal must be achieved through a treatment technique (enhanced coagulation or enhanced softening) unless a system meets alternative criteria.

The cost to comply with MCL and TT regulation is much higher than for MR violations. As described earlier, complying with MCL and TT regulations requires good maintenance of the water facilities, proper application of the treatment process, and appropriate operation of water facility staff, while complying with MR regulations only requires a PWS to regularly take and report samples. State agencies and the EPA can conduct formal enforcement actions such as an administrative order, a judicial referral, or a civil penalty, as well as informal actions such as issuing a violation notice, requiring public notification, and bilateral agreement (U.S. EPA 1986). Although U.S. EPA (1986) only specified the general principle of choosing the appropriate enforcement response, stronger enforcement action is usually conducted for severe health-based MCL violations and weaker enforcement actions are applied to MR violations. In the case of MCL violations, the state may issue administrative orders that require a PWS to hire engineers to conduct a feasibility study and a sanitary survey; PWSs may also be required to conduct new construction or replace parts of their pipes. However, the state might issue administrative orders that only require a PWS committing a MR violation to submit the missed sample.

The enforcement dataset of SDWIS shows that the percentage of state administrative orders is more frequent in MCL violations compared to MR violations (8.83 percent versus 4.03 percent), suggesting stricter enforcement of MCL violations. Interestingly, the percentage of “back to compliance” is smaller in MCL violations than it is for MR violations (24.33 percent versus 35.90 percent), indicating that MR violations may be relatively easy to fix, while MCL violations are more difficult to resolve. Furthermore, MCL and TT violations require, respectively, Tier 1 and Tier 2 public notices, while MR violations only require Tier 3 notice, which is considered less important and less urgent.Footnote ⁵

In summary, the cost of compliance for MCL, TT, and MR violation regulation varies greatly. Since publicly and privately owned PWSs have distinct objectives and face possible differences in the cost of compliance with the three types of regulations, different types of PWSs are likely to commit one type of violation instead of others when water quality problems arise. We now provide a brief description of our dataset used in the empirical model.

4. Model Specification

In this section, we discuss our econometric framework to identify the relationship between PWS ownership and types of violations. We first create a set of dummy variables to present MCL, MR, and TT violations, each taking integer values and representing the counts of certain types of violations that happened in a PWS in any given year. Our violation records include PWSs from 1950 to 2017. However, the data before 1988 is scarce. Therefore, we constructed a panel dataset for each PWS across years and only kept the records after 1988 (dropping about 5 percent of all the records), when the Lead and Copper Rule was enforced, which initiated the time when the majority of violations took place. The violation dataset is then merged with the water system dataset on a PWS-year basis with the water system data. We converted the Population variable into a set of dummy variable Population Categories, i.e., one dummy for each of the population categories with the cutoff points 500, 3,300, and 10,000 to better control for the scale of PWSs. Our population categories follow EPA designations in the 2013 National Public Water Systems compliance report, and the same categorization is also used in Allaire et al. (Reference Allaire, Wu and Lall2018).

If a PWS was deactivated before 2017, its violation record would only be kept up to the deactivation year in the panel dataset. Our panel dataset contains 6,384,636 violation records from 317,587 PWSs. Note that the panel dataset is imbalanced, as some PWSs were deactivated before 2017. Our constructed dataset enables us to track down the violation information for a PWS in a given year.

We specify the following regression model

$$y_{it} = \gamma \, \ast \, Ownership_{it} + \beta X_{it} + \eta _l + \eta _t + \epsilon _{it}\comma \;$$

where y _it is the dependent variable recording the number of occurrences of a certain violation for PWS i in year t. As noted before, the types of violations considered in the empirical model include MCL, MR, and TT violations.Footnote ⁷ The dummy variable Ownership consists of a set of dummy variables, including Public and Other, using the private ownership as the baseline for comparison. The X _it is a set of control variables associated with the PWS. Our control variables include the dummy variables GW, CWS, NTNCWS, Wholesaler, Daycare, Primacy_state, Primacy_territory, Population Categories, and the continuous variable Connections. The η _l captures the location fixed effects and η _t includes the set of time fixed effects. The idiosyncratic error term is denoted as ε_it. We specify several models, allowing for different sets of controls. In some specifications, we include the interaction terms of the dummy Ownership and the dummy Large, i.e. Public*Large and Other*Large, which enables us to better control for the correlation between the ownership of and the scale of a PWS, since large PWSs may have more resources to comply with NPDWR (Bhattacharyya et al. Reference Bhattacharyya, Harris, Narayanan and Raffiee1995). The time fixed effects are at the yearly level and the location fixed effects are controlled at either the state level or the municipal level.Footnote ⁸

To obtain unbiased estimates, our identification assumption requires

$$E\lpar {Ownership_{it} \, \ast \, \epsilon_{it}{\rm \vert }X_{it}\comma \;\;\eta_l\comma \;\;\eta_t} \rpar = 0\comma \;$$

which assumes, after controlling for observed PWS characteristics and unobserved time-invariant location and time fixed effects, confounders do not exist that both affect ownership types and the occurrence of violations. To control for these potential confounding factors in our regression model, we use the state level or municipal level fixed effects to control for location heterogeneities in terms of regulations, transaction costs, and economic conditions, although time-varying confounders may still bias our coefficient estimate. The majority of changes of PWS ownership type happened at the turn of the 20^th century and during the 1980s (Troesken and Geddes Reference Troesken and Geddes2003; Arnold Reference Arnold2009; Brubaker Reference Brubaker2003), so it is reasonable to assume that there is little influence of time-varying confounders during our data window from 1988 to 2017, when only less than one percent of PWSs experienced an ownership change. We also use a variety of model specifications to assess the robustness of estimation.

5. Results

Our first set of regression results is presented in Table 5. The dependent variables are the number of MCL, MR, and TT violations that occurred in a given year for a PWS in Panels A, B, and C, respectively. The location fixed effects, wherever controlled for, are at the state level. Column (1) includes the ownership type dummy variables and the PWS associated control variables defined earlier. We did not include the year or the location fixed effects in Column (1). Column (2) adds the year fixed effects, and Column (3) adds the location fixed effects, in addition to the variables included in Column (1). Column (4) adds both the year and location fixed effects based on Column (1). Column (5) includes interaction terms of the ownership type dummies and the dummy Large, i.e., Public*Large and Other*Large, with year and location fixed effects. Panel A in Table 5 suggests that the publicly owned PWSs commit significantly more MCL violations compared to privately owned PWSs, and the estimates for the dummy Public decrease from 0.00984 to 0.00453 as we add more controls from Column (1) to Column (5). The largest decrease appears from Column (2) to (3), where the coefficient changes from 0.0083 to 0.00534, suggesting that location fixed effects explain a large amount of variations in the MCL violations. As expected, our results also suggest that large PWSs commit significantly fewer MCL violations. In addition, the interaction effect of Public*Large in Column (5) of Panel A is significant, suggesting that the difference between public and private ownership is further moderated by the scale of the PWSs.

Table 5. Regression Results of Violation Occurrence: State Fixed Effects

Notes: *** indicates P < 0.001, ** indicates P < 0.05, and * indicates P < 0.1. Standard errors are in the parentheses below the estimated coefficients. For Panels A, B, and C, the dependent variables are the number of MCL, MR, or TT violations committed by a public water system in a given year, respectively. The Public stands for the public ownership type; Other represents the other ownership type; Large stands for large PWS, Public*Large stands for large publicly owned PWS, and Other*Large stands for large PWS with the ownership type “Other.” Column (1) includes the ownership type dummy variables, Public and Other, and control variables do not include the year or the location fixed effects. Column (2) adds the year fixed effects, and Column (3) adds the location fixed effects, in addition to the variables included in Column (1). Column (4) adds both the year and location fixed effects based on Column (1). Column (5) includes interaction terms of the ownership type dummies and the dummy Large, i.e., Public*Large and Other*Large, with both year and location fixed effects. Location fixed effects controlled for are at the state level.

Panel B of Table 5 presents the regression results of the MR violation. Our results consistently show the publicly owned PWSs commit significantly fewer MR violations with the coefficient ranges from −0.085 to −0.095 compared to privately owned PWSs. One possible explanation is that privately owned PWSs might not submit monitored samples to their primacy agencies and intentionally commit MR violations to avoid more expensive MCL violations when water quality issues arise with the PWS water facility or treatment process. The estimates for Large are not consistent across all specifications and are negative and significant at a 5 percent level in Column (5) when interaction terms such as Public*Large are included.

Panel C presents the regression results of the TT violation. Regression results suggest that publicly owned PWSs commit significantly more TT violations compared to privately owned PWSs, and the estimated coefficient ranges from 0.002 to 0.000964. Adding more controls gradually reduces the magnitude of the coefficient. Table 5 provides consistent evidence that privately owned PWSs commit more MR violations while reducing potential MCL and TT violations.

Table 6 is similar to Table 5, except we use a stronger location control, the municipality fixed effects instead of the state fixed effects. Panel A shows that publicly owned PWSs commit significantly more MCL violations than privately owned PWSs. Panel B suggests that the publicly owned PWSs commit significantly fewer MR violations compared to privately owned PWSs, and panel C shows that publicly owned PWSs commit slightly more TT violations than privately owned PWSs. Table 6 reconfirms that coefficients estimated for treatment variable Public are robust after controlling for different levels of location fixed effects.

Table 6. Regression Results of Violation Occurrence: Municipality Fixed Effects

Notes: *** indicates P < 0.001, ** indicates P < 0.05, and * indicates P < 0.1. Standard errors are in the parentheses below the estimated coefficients. For Panels A, B, and C, the dependent variables are the number of MCL, MR, or TT violations committed by a PWS in a given year, respectively. Location fixed effects controlled for are at the municipal level.

Comparing Tables 5 and 6, we find that coefficient estimates for Public become smaller after controlling for the municipality fixed effects instead of the state fixed effects, indicating that municipality fixed effects explain a larger amount of variations for the MCL and TT violations. In addition, we find that the interaction term between Public and Large is smaller for MCL and TT violations and no longer significant for MR violations after controlling for municipality fixed effects, implying that large publicly owned PWSs may commit more MCL and TT violations than privately owned and small or medium PWSs regardless of the degree of location heterogeneities controlled. This result may also be related to the underreporting behavior of privately owned and small or medium PWSs, since large publicly owned PWSs are not significantly committing more MR violations when controlling for municipality fixed effects, as shown in Panel B of Table 6.

Table 7 presents the regression results using the number of Health-Related violations of a PWS in a given year as the dependent variable. Panel A controls for the state-level fixed effects and Panel B controls for the municipal-level fixed effects. Interestingly, we find the publicly owned utilities incur significantly more Health-Related violations compared to privately owned utilities. While a large utility generally commits a lower Health-Related violation, the interaction term Public*Large is positively significant. Adding more controls reduces the magnitude of coefficient estimates, and using a municipality-level fixed effects model further reduces the magnitude, though the coefficient is highly significant across all specifications. We only keep several key variables in the tables and leave the full model estimation results to the Supplementary Appendix, Tables A2 and A3. Based on the full model, we find the community water system (CWS) significantly increases all types of violations; the non-transient, non-community water system (NTNCWS) also significantly increases all types of violations, compared to the baseline transient non-community water system (TNCWS). In addition, if a PWS has a groundwater (GW) source, the PWS is more likely to incur MCL, TT, and Health-Related violations but less likely to incur MR violations.

Table 7. Regression Results of Health-Related Violation

Notes: *** indicates P < 0.001, ** indicates P < 0.05 and * indicates P < 0.1. Standard errors are in the parentheses below the estimated coefficients. For Panels A and B, the dependent variables are the number of Health-Related violations committed by a PWS in a given year, respectively.

Our main results reveal systematic differences between the public and private utilities on the types of violations. We find strong evidence that publicly owned utilities are more likely to commit costly violations such as MCL and TT, and privately owned utilities are more likely to commit less costly MR violations. Our results are consistent with the story that privately owned utilities may intentionally commit MR violations instead of MCL and TT violations since the MCL and TT violations are more costly to resolve. We also find that public utilities are more likely to commit Health-Related violations. However, since privately owned utilities commit more MR violations, some Health-Related violations are less likely to be detected due to more MR violations for private utilities. We do not believe our results indicate drinking water provided by the public utility is less safe compared to water provided by the private utility. Due to data limitations, we are unable to fully explore this hypothesis. Future research can combine drinking water-related disease with the drinking water source to determine whether there is a systematic difference in terms of drinking water-related disease between public and private drinking water utilities. We also use a Tobit model where the dependent variable is the cumulative violation records, as the dependent variable is highly skewed to zero. The regression results for the Tobit model are provided in the Supplementary Appendix, Table A4. Our main conclusions remain the same, and the regression results are consistent with fixed effects models on the directions and significance of major coefficients, though the magnitudes of the coefficients are different after we change the dependent variable.