4.1 Identification using difference in difference

Our initial plan is to restrict the treatment group to six severely-affected districts, and to compare them with the ten marginally-affected districts, with the premise that severely-affected districts should face worse health outcomes as compared to the marginally-affected ones. In order to distinguish these ten districts from the only one unaffected Narmada district, we call the former ‘marginally-affected’ districts in figure A1. However, in order to increase the sample size of the control group and to make it stronger with a ‘true’ control who were not affected by the earthquake, we also include the other surveyed districts of the neighboring states of Maharashtra, Rajasthan and Madhya Pradesh in the control group, along with the unaffected Narmada district of Gujarat. The first level of difference is, therefore, calculated across space, that is, among same age-cohorts belonging to six districts of Gujarat, with the ten marginally-affected districts and one unaffected district of Gujarat, plus all surveyed districts of Maharashtra, Rajasthan and Madhya Pradesh as listed in online appendix table A1.

Since lack of nourishment for children in-utero or in the age group of 0–3-years can bring disastrous outcomes in later life, we aim to restrict our treated group to the children born from 1998 to 2001, aged 3–6 years during 2004–05. The data collection for IHDS-1 was done from November 2004 to October 2005, with most of it being done in 2005. We restrict our treated group to those children whose age is reported as 4 or 5 in the survey year 2005 and whose age is reported as 3–5 in the survey year 2004.Footnote ⁸ With an objective of restricting our treated group to the children born in 2001 or before, we include only those children in the sample who report being 4 or 5 years old in survey year 2005.Footnote ⁹ However, our results are robust to inclusion of children whose age is reported as 3 in the survey year 2005.Footnote ¹⁰ Moreover, to ensure that all individuals from our treated group have been truly exposed to the earthquake, we limit the sample to females in households, who have been in the same place at least for the last ten years.Footnote ¹¹ Figure 1 explains the construction of the treatment and control cohorts.

Figure 1. Timeline projecting treatment and trajectory of height.

One may wonder why we choose to study two cohorts, knowing that ex ante, one expects not to observe a difference between young adults in treated and control regions as they are in the last stage of physical development. However, our double difference strategy helps to alleviate the concerns related to pre-treatment differences in health outcomes of children in the severely-affected region and other region.Footnote ¹² In order to control for pre-treatment differences between the earthquake-affected and unaffected regions, we need a counterfactual group who are unlikely to be affected by the earthquake in a way the outcomes of the treated cohort should be. Therefore, the second level of difference across time includes cohorts aged 18 to 23 years at the time of the survey. By choosing this as the counterfactual cohort we ensure that the youngest child in this cohort could be 14 years old at the time of the earthquake. It is important to note that this cohort has already passed the crucial age where malnutrition due to shock was expected to reduce growth. Moreover, the fact that puberty in females is complete by the age of 17 (Marcell, Reference Marcell, Kliegman, Behrman, Jenson and Stanton2007), encourages us to choose 18 as the lowest age for the counterfactual cohort. So, we assume that this cohort is unlikely to be affected by the earthquake and will help in differencing out pre-treatment differences in the affected and unaffected regions.

Since anthropometric information for the elder group is collected only from the ever-married women, our analysis is restricted to female cohort for height and ZHFA. However, ZHFA could not be calculated for the individuals older than 23 years due to unavailable reference data. Therefore, in all our primary specifications, our counterfactual cohort gets restricted to 18–23 years old in the survey year. However, the information on heights being available for the cohort up to 49 years, as we check the specification with 18–36 being the counterfactual, our estimates for height remain similar in magnitude.Footnote ¹³ For the analysis using the double difference strategy, and for the robustness checks, we restrict our sample to the individuals surveyed in four states – Gujarat, Maharashtra, Rajasthan and Madhya Pradesh – as listed in online appendix table A1. For falsification tests, we also include the districts of the Bihar, Chhattisgarh and Uttar Pradesh in the analysis.Footnote ¹⁴

This identification strategy is based on the comparisons of both the height and ZHFA outcomes of females belonging to the same cohort in severely-affected versus other districts. We try to elaborate this in table 1, which has the unconditional means of health outcomes of different cohorts in different regions. In Actual Experiment, we compare the health outcomes of the Older Cohort females (14 to 19 years old at the time of the earthquake) unlikely to be affected by the earthquake of 2001, to the Younger Cohort females directly affected, being in-utero or under the age of 3 years during the earthquake. These comparisons are also made in both the treated and control regions.

Table 1. Unconditional means of health outcomes by cohort and regions

Notes: Full sample of 98 districts including control district of neighboring states.

Robust standard errors are clustered at the district-age level.

In the actual experiment, younger cohort consists of females who were in-utero or under the age of 3 in 2001. Older cohort consists of females aged 14–19 years old at the time of the earthquake in 2001. In the controlled experiment, younger cohort consists of 14–19 years old females, and older cohort consists of 20–45 years old females.

Data source: IHDS-1.

We find that older cohort females belonging to the severely-affected (treated) region may have both higher height and lower negative ZHFA as compared to those who belong to the control region. This may indicate better health outcomes for the older cohort in the severely-affected region as compared to marginally-affected and unaffected regions. But the younger cohort that is expected to be affected due to the earthquake has marginally lower height, indicating poor health outcomes among them in the severely-affected regions. Under the assumption that health outcomes in the absence of the earthquake would have been systematically indifferent in both the regions, we can interpret the difference in these differences as the effect of the earthquake on the health outcomes. Table 1 indicates that the unconditional average height seem to be 5.21 cm lower for the younger cohort in the severely-affected region, but we do not get a statistically significant difference in ZHFA.

In order to test the implications of our assumption, we conduct a controlled experiment for height by comparing the means of health outcomes of two cohorts whom we expect to remain unaffected by the earthquake. We choose 18 to 23 and 24 to 49 year old women for this purpose (who were 14 to 19 and 20 to 45 years old respectively at the time of earthquake in 2001). In column (3), we find that the unconditional double difference of mean height is not significant. This result provides supportive evidence that our estimates are not influenced by any systematic differences in the two regions. Under the assumption that, conditional on a host of observables and district-specific or time variant unobservables, differences across different cohorts in each of the outcomes would be similar between severely-affected - treated districts and unaffected or marginally-affected - control districts in the absence of the earthquake, we estimate the following equation in our first specification:

(1)\begin{align}{H_{ihjt}} & = \beta ({\textrm{Younger Cohor}{\textrm{t}_i} \times \textrm{Severely Affected Regio}{\textrm{n}_j}} )\nonumber\\& \quad + {\delta _t} + {\alpha _{jt}} + {\gamma _{sy}} + \mu {X_h} + {\varepsilon _{ihjt}},\end{align}

where ${H_{ihjt}}$ is the health outcomes measured by height (or ZHFA in alternative specification) for the individual i who belongs to household h in district j and birth year t. Footnote ¹⁵ Younger Cohort_i is a dummy variable indicating whether the individual was in-utero or under age of three at the time of the earthquake (=1). $\textrm{Severely Affected Regio}{\textrm{n}_j}$ is a dummy variable indicating the individual belonging to one of the six severely-affected districts. We include birth-year fixed effects ${\delta _t}$ to account for unobservable time-variant changes that might have happened in both regions, which could also affect the health outcomes. ${\alpha _{jt}}$, capturing the time-trend across districts, controls for the unobserved time-variant differences among districts which could cause differential developmental outcomes irrespective of the earthquake. All our estimates include survey-year fixed effects denoted by ${\gamma _{sy}}$. ${\boldsymbol{X}_h}$ controls for other household-specific covariates such as ethnicity, religion, and residence status, which may also affect the health outcomes of the children.Footnote ¹⁶ ${\varepsilon _{ihjt}}\;$is the error term with the usual assumptions. Descriptive statistics about the background characteristics of individuals disaggregated by the region are provided in online appendix table A8.

Since inference based on the clustered standard errors may be misleading if the number of clusters is less (Roodman et al., Reference Roodman, MacKinnon, Nielsen and Webb2019), throughout all our regression estimates, we cluster the standard errors at the district-age level. However, our results remain qualitatively unchanged even after clustering the standard errors at the district level.Footnote ¹⁷

4.2 Identification using earthquake intensity as primary evidence

The above-mentioned identification strategy may suffer from a few potential concerns. First, it is possible that some other shocks with the potential of affecting health outcomes may have occurred in one of the regions during the same time, causing treated and control districts to have different health outcomes irrespective of the earthquake. This is difficult to address in the above difference in difference framework using cross-section data. Second, the limited sample on unaffected districts (counterfactuals) persuades us to consider the moderately-affected districts as counterfactuals as well. This has the potential of generating bias in our estimates. Even though we try to address that concern using districts from other neighboring states as counterfactuals as well, it is difficult to establish that those would be true controls. Hence the Difference in Difference strategy explained earlier requires validity of much stronger assumptions. Third, the above strategy treats all the districts in the severely-affected region uniformly. However, the intensity of the earthquake is higher closer to the epicenter and reduces with the distance away from the epicenter.

Therefore, in order to ensure that the observed health effects in the severely-affected regions are due to the earthquake, our primary specification is a different model, where we use another variant of treatment capturing intensity of the earthquake data from Hough et al. (Reference Hough, Martin, Bilham and Atkinson2002). Due to scarcity of instrumental recordings of the intensity at various locations, Hough et al. (Reference Hough, Martin, Bilham and Atkinson2002) have used the extensive news articles on print media and electronic media in the United States and India, along with internet-based sources, to assign the MMIs at various locations. Based on the severity of ground shaking and destruction, these MMIs were assigned (for details, please see Hough et al. (Reference Hough, Martin, Bilham and Atkinson2002)). MMIs are interpreted as point data. Hough et al. (Reference Hough, Martin, Bilham and Atkinson2002) show that these intensities were inversely related to the distance from the epicenter. We use this data on MMIs for all the severely-affected and marginally-affected districts of Gujarat. Since MMIs are reported from several locations along with their geo-coded locations within the same district, we find the average MMI for each district affected by the earthquake and surveyed in IHDS-1. We re-tabulate MMIs for all the severely- and marginally-affected districts as presented in online appendix tables A2a-A2c. Since MMIs are reported from several locationsFootnote ¹⁸ within the same district, we take an average to get a representative MMI for each district. Online appendix table A22 shows the average intensity for every district. Since the IHDS-1 data does not provide the geo-coded locations of the surveyed households, we had to use the average intensities at the district level.

Using this variable of intensity, we estimate the following equation:

(2)\begin{equation}{H_{ihjt}} = \; \beta ({\textrm{Younger Cohor}{\textrm{t}_i} \times \textrm{Intensit}{\textrm{y}_j}} )+ \; {\delta _t} + \; {\alpha _{jt}} + \; \mu {X_h} + {\varepsilon _{ihjt,}}\end{equation}

where all other variable specifications remain the same as in equation (1) Intensity_j measures the MMI of the earthquake in district j. This specification helps us to check if districts with higher intensities have worse health outcomes than the districts with lower intensities.

In order to check the validity of our identification strategy, we further generalize equation (2) to estimate age-specific impact. We construct seven age dummies that are a dummy for each age 4, 5, and 18 to 22, with individuals aged 23 years in 2005 being the reference category:

(3)\begin{align}{H_{ihjt}} & = \mathop \sum \limits_{l = 4}^{l = 5} ({\textrm{ag}{\textrm{e}_{il}} \times \textrm{Intensit}{\textrm{y}_j}} ){\gamma _{1l}} + \mathop \sum \limits_{l = 18}^{l = 22} ({\textrm{ag}{\textrm{e}_{il}} \times \textrm{Intensit}{\textrm{y}_j}} ){\gamma _{1l}} + {\delta _t} + {\alpha _{jt}}\nonumber\\& \quad + \mu {X_h} + {\varepsilon _{ihjt}},\end{align}

where age_il is a dummy variable indicating whether individual i is of age l in the survey year 2005. Each coefficient ${\gamma _{1l}}$ can be interpreted as an estimate of the impact of the earthquake on a given l year cohort. Since individuals aged 18 and older in 2005 would have been at least 14 years old at the time of the earthquake in 2001, we do not expect their health outcomes measured by height and ZHFA to be affected through the channel of early-life malnutrition caused by the earthquake.

We plot the coefficients ${\gamma _{1l}}$ in figure 2 for the outcome variables height and ZHFA. Each dot on the middle line is the coefficient of the interaction between age dummy and the intensity measure. The dashed lines above and below the solid line connect the 95-per cent confidence interval for each coefficient. Since our cohort-based analysis as mentioned in specification (2) can only capture average effect on the treated (younger) cohort, the figure 2 helps us to identify age-specific linear impact, along with presenting evidence for parallel trends (Duflo, Reference Duflo2004).

Figure 2. Coefficients of height and ZHFA on the interactions between age in 2005 and earthquake intensity in the affected districts of Gujarat.

In figure 2, none of the coefficients for the age cohorts 18 to 22 is significantly different from zero, which supports our a priori assumption of parallel trends. As the impact of the earthquake, we expect significantly negative coefficients for both the 4 and 5 year old cohorts. However, the negative impact on height seems to be primarily driven by the effect on a 4-year old cohort, as the coefficient for age 5 is small in magnitude and not statistically significant. Individuals whom we expect to be in-utero or were less than a year old at the time of the earthquake (i.e., aged 4 years old in 2005), have significantly negative coefficients, as expected. Similarly, for the outcome variable ZHFA, none of the coefficients of the interaction terms, except for that of age 4, is significantly different from zero, which indicates the negative impact on affected children who may have been in-utero or less than a year old during the disaster.