Sanitation investments in India led to large increases in water pollution, which offset the intended health benefits of increased latrine construction
The importance of sanitation investment for improving human health in developing countries is widely recognised by policymakers and researchers. Worldwide, 688 million people practised open defecation in 2016, which is estimated to have caused 432,000 deaths due to diarrhoea in that year (Prüss-Üstün et al. 2019). To address these issues, developing countries such as India and China have provided significant subsidies for the construction of latrines (toilets). The direct health benefits (e.g. reduced child mortality, improved child growth) of latrine construction have been well-documented (Geruso and Spears 2018, Cameron et al. 2022).
But little is known about the unintended negative externalities of latrine construction due to poor treatment of faecal sludge, which can offset the direct health benefits. The constructed latrines accumulate a large volume of faecal sludge, which must be emptied periodically by vacuum trucks or by hand. The emptied faecal sludge should then be treated by wastewater treatment plants to disinfect the remaining active pathogens. However, due to insufficient infrastructure, the emptied faecal sludge is instead, in many cases, dumped into rivers, thus polluting the rivers. These water pollution externalities may offset the direct positive effects of reduced open defecation.
In my research (Motohashi 2023), I examines the negative externalities of latrine construction on water quality and health in the context of India's nationwide sanitation policy, the Swachh Bharat Mission (SBM). I find that latrine construction under the SBM increases river pollution by 72%. While the latrine construction reduces diarrhoeal mortality overall, this positive health effect is two-thirds smaller in areas with lower treatment capacities where water pollution externalities are consequently larger. These findings suggest that unintended water pollution externalities offset positive health effects.
Large-scale latrine construction policy in rural India
I look at the case of the SBM, the world's largest programme of latrine construction. The SBM has subsidised the construction of over 100 million latrines in rural India since 2014. The amount of subsidy available under the SBM is up to 150 US dollars, covering most of the construction cost of latrines. With such a big push, most districts have achieved almost universal latrine coverage by the target date of 2019.
To investigate how this massive latrine construction affects water quality, I use administrative panel datasets on the district-level number of latrines from 2012 to 2019 under the SBM and the water quality of 1,189 monitoring stations along rivers in 337 districts from 2007 to 2019 (Figure 1). I combine these with district-level diarrhoeal post-neonatal mortality estimates to examine the effects on health. The district-level analysis with extensive spatial coverage of these datasets allows me to examine the negative externalities that extend beyond villages, which was not fully captured in past studies relying on village-level field experiments.
Figure 1: Distribution of water quality monitoring stations in India
Notes: This figure shows water quality monitoring stations in orange dots, district boundaries in black lines, and rivers in blue lines.
Methodology: Exploiting geographical variation in soil characteristics that affect latrine construction
To estimate the causal effects of latrine construction, I use an instrument variable (IV) design, exploiting geographical variation in Available Water Capacity (AWC), a proxy for the soil infiltration rate, as an instrument for the number of latrines. Higher soil infiltration rates (lower AWC) increase the risk of groundwater contamination in nearby wells from the faecal sludge accumulated in latrines. To address this risk, an official technical guideline (CPHEEO 2013), which became effective since the SBM's inception in 2014, requires either greater distances between latrines and wells or the addition of impervious materials inside latrines in areas with high infiltration rates. So, lower AWC increases the difficulty and cost of latrine construction after the SBM started in 2014. Indeed, I find lower AWC is associated with a smaller increase in latrines during the post-SBM period in the first stage.
Figure 2: Event study plots of the effects of Available Water Capacity on water quality and health
Notes: This figure shows the regression coefficients of the logarithm of faecal coliform (Panel A) and diarrhoeal post-neonatal mortality per 1,000 people (Panel B) on the interaction terms between Available Water Capacity and year dummies.
Latrine construction increases river pollution but improves health overall
I find that one additional latrine per square kilometre increases river pollution (faecal coliform) by 3%. The total effect of the SBM is estimated to be a 72% increase in river pollution, which is a large effect. However, one additional latrine per square kilometre reduces diarrhoeal mortality by 1.3% (from a baseline mortality rate of 2.3 per 1000 people) — a 36% decrease in the incidence of diarrhoeal mortality in total under the SBM. This positive overall health effect suggests that the direct positive health effect outweighs the negative externality on health due to water pollution in local waterways.
Negative externalities are larger in areas with lower treatment capacities
I show that the effects of latrine construction on water quality vary by the level of complementary treatment of faecal sludge. Sufficient infrastructure to treat faecal sludge can minimise the dumping of faecal sludge - the most common form of such infrastructure takes the form of sewage treatment plants (STPs). So, I compare the effects between areas with higher and lower treatment capacities of STPs in the pre-SBM period. I find that the negative externality on water quality is eliminated in areas with higher treatment capacities. Conversely, in areas with lower treatment capacities, the negative externality on water quality is found to be substantial, which suggests that the dumping of faecal sludge is the mechanism of the negative externalities on water quality.
The net health effect of the SBM is a 26% decrease in diarrhoeal mortality in states with lower treatment capacities (where water pollution is larger), about two-thirds less than the 71% decrease in states with higher treatment capacities. The negative externality on health through the water pollution channel is further supported by additional heterogeneity analysis by the exposure to river pollution, measured as a fraction of people living near rivers based on nighttime luminosity. I find that the positive effects on diarrhoeal mortality are smaller in districts with higher exposure to river pollution.
Moreover, I show that the water pollution externalities of latrine construction spill over to downstream districts by analysing districts in the upstream and downstream along rivers. When upstream areas have lower treatment capacities, upstream latrine construction increases river pollution downstream (similar magnitude as the baseline results), and the positive health effects become insignificant.
Policy implications
In terms of the effectiveness of the policy as a whole, my back-of-the-envelope calculations show that the net health benefits have been worth the subsidy cost of the SBM policy. Still, improving treatment of faecal sludge would increase the health effects even more for a low additional cost. The district-level additional health benefits (18.1 million USD) would be larger than the additional construction and operation costs (11.5 million USD) of higher treatment capacity. Investing in effective treatment of faecal sludge can make sanitation policies even more effective.
Editor’s Note: The original version of this column was published on the World Bank Development Impact Blog.
References
Cameron, L, P Gertler, M Shah, M L Alzua,S Martinez, and S Patil (2022), “The dirty business of eliminating open defecation: The effect of village sanitation on child height from field experiments in four countries.” Journal of Development Economics: 102990
CPHEEO (2013), “Manual on sewerage and sewage treatment systems - Part A Engineering.” Central Public Health & Environmental Engineering Organisation (CPHEEO), Ministry of Housing and Urban Affairs, Government of India.
Geruso, M, and D Spears (2018), “Neighborhood sanitation and infant mortality.” American Economic Journal: Applied Economics, 10(2): 125–62.
Motohashi, K (2023), “Unintended consequences of sanitation: Negative externalities on water quality and health in India.” Mimeo.
Prüss-Üstün, A, J Wolf, J Bartram, T Clasen, O Cumming, M C Freeman, B Gordon, P R Hunter, K Medlicott, and R Johnston (2019), “Burden of disease from inadequate water, sanitation and hygiene for selected adverse health outcomes: an updated analysis with a focus on low-and middle-income countries.” International Journal of Hygiene and Environmental Health, 222(5): 765–777.