2. Background on interdecadal rainfall variability

Indian agriculture depends heavily on the summer monsoon, which occurs during June, July, August and September (Krishna Kumar et al., Reference Krishna Kumar, Rupa Kumar, Ashrit, Deshpande and Hansen2004). Because India's climate is semi-arid, wetter monsoons increase agricultural output, and drier monsoons decrease it (Das, Reference Das1995; Jayachandran, Reference Jayachandran2006). Monsoon rainfall exhibits high interannual variability, as shown in figure A1 of online appendix 1. The monsoon also undergoes interdecadal variability, in the form of wet and dry phases that typically each last for about three decades (Pant and Kumar, Reference Pant and Kumar1997). Figure 1 in the main text smoothes national, annual rainfall with a moving average filter, to highlight the regimes.

The monsoon regimes cause average rainfall to vary more from decade to decade than it would if rainfall was independent and identically distributed (i.i.d.), as discussed in greater detail in online appendix 1. This persistent decadal variation means that lagged rainfall has predictive value for future rainfall. If rainfall were i.i.d., then lagged rainfall would not have this predictive element. Rational farmers should notice these persistent rainfall variations and update their future rainfall expectations in response. This updating could occur even if farmers were not aware of the existence of the monsoon regimes, per se. On the other hand, if rainfall were i.i.d., lagged rainfall would have no predictive value, and it would be irrational for farmers to update their rainfall expectations in response to it. The statistical significance of the decadal variations allows us to interpret a farmer's response to lagged rainfall as evidence of rational adaptation, rather than as an indicator of irrational behavior.Footnote ⁵

The monsoon regimes are not geographically homogeneous. There is significant spatial variation in the length and timing of the regimes (Subbaramayya and Naidu, Reference Subbaramayya and Naidu1992). In particular, rainfall in the southern peninsula and the easternmost region tends to be out of phase with the rest of the country (Wang, Reference Wang2006). Figure 2 displays smoothed rainfall graphs for India's five meteorological regions, highlighting the spatial variation. Providing more detail, online appendix 4 presents maps of district rainfall from the previous decade, for the three survey years of the REDS data set and at four decade intervals for the WB data set. We choose rainfall from the previous decade as a rough measure of the current monsoon regime (Kripalani and Kulkarni, Reference Kripalani and Kulkarni1997). The spatial variation in recent rainfall allows us to include year fixed effects in the regressions and, hence, distinguish rainfall adaptation from time trends in irrigation and crop choice.

Figure 2. Spatial variation of the interdecadal variability of the Indian monsoon

Notes: This figure graphs the 31-year moving average of the summer monsoon rainfall, measured in millimeters for India's five meteorological regions. The horizontal line represents mean rainfall for that region.

Source: The rainfall data are from the India Institute of Tropical Meteorology's Homogeneous Indian Monthly Rainfall Data Set (1871–2008). The figure is constructed based on the author's calculations.

3. Theoretical framework

We present climate and agricultural models and derive tests for adaptation.

3.1. Climate model

We model the monsoon regimes as a hidden Markov process. Let s _t indicate the monsoon regime in year t, with s _t =0 denoting a dry regime and s _t =1 denoting a wet regime. Year t rainfall can be written as:

(1) $$r_t=\theta_0 + \delta s_t + u_t,$$

where θ₀ is the average rainfall during a dry regime, $\theta_{0} + \delta$ is the average wet regime rainfall, and u _t represents year-to-year rainfall variability. The monsoon regimes are persistent but not permanent, and they switch according to a Markov process. During a dry regime, the probability of switching to a wet regime during the next period is p ₀. During a wet regime, the probability of switching to a dry regime is p ₁. Each year, farmers observe r _t and use this information to update their belief about the current regime state, which they do not observe. A farmer's belief about the current regime state determines his expectation of the next period's rainfall.

3.2. Agricultural model

In this model, each farmer lives for two periods. In each period t, the farmer allocates his wealth, w _t , between an irrigation asset, i _t , and another agricultural asset, a _t , such that a _t +i _t =w _t .Footnote ⁶ The farmer also chooses a crop portfolio each period. The farmer has one unit of land, which he divides between a drought-tolerant crop and a crop that is relatively more sensitive to drought. Let ρ _t be the area planted with the drought-tolerant crop, and let 1−ρ _t be the drought-sensitive crop area.

Profits are determined by the asset mix, the crop portfolio, and rainfall r _t . For tractability, we assume a quadratic profit function of the form:

(2) $$\eqalign{\pi_{t} &= \beta_{a}a_{t}+\beta_{i}i_{t}+\beta_{\rho}\rho_{t} + {1\over 2}\delta_{aa}a_{t}^{2}+{1\over 2}\delta_{ii}i_{t}^{2} +{1\over 2}\delta_{\rho\rho}\rho_{t}^{2}+\delta_{\rho i}\rho_{t}i_{t}+\delta_{ir}i_{t}r_{t} \cr &\quad + \delta_{\rho r}\rho_{t}r_{t}+\delta_{r}r_{t}+ \epsilon_t,}$$

where π _t is profits per acre and ε _t is a mean zero productivity shock. To establish our adaptation tests, we assume that:

1. (1) Profits are increasing in rainfall (δ _r >0). This assumption is consistent with earlier work on India (Jayachandran, Reference Jayachandran2006; Cole et al., Reference Cole, Healy and Werker2012), and is verified in online appendix 5.

2. (2) The return to irrigation is higher during periods of low rainfall (δ _ir <0). This assumption is verified in online appendix 5.

3. (3) The drought-tolerant crop is less profitable, on average, than the drought-sensitive crop ( $\beta_{\rho}\lt 0$ ). This assumption is necessary to ensure that farmers do not plant all their land with the drought-tolerant crop.

4. (4) Low rainfall reduces the profitability of the drought-tolerant crop less than it reduces the profitability of the drought-sensitive crop ( $\delta_{\rho r}\lt 0$ ). This assumption comprises our definition of the drought-tolerant crop.

3.3. Maximization problem

Each farmer maximizes:

(3) $$u(c_{1})+\beta E_{1}[u(c_{2})],$$

subject to:

(4) $$c_{1}=w_1+\pi_{1}-w_{2} \hbox{and } c_{2}=w_{2}+\pi_{2},$$

where 0<β<1. For tractability, we assume constant absolute risk aversion utility of the form $u(c_{t})=-e^{-\eta c_{t}}$ . The timing of the model is as follows. To begin, the farmer chooses his first-period assets and crop portfolio, based on initial wealth and rainfall expectations. Next, first-period rainfall occurs and first-period profits are determined. With these profits in hand, the farmer chooses how much to consume in the first period and how much wealth to bring into the second period. The farmer also chooses his second-period asset mix and crop portfolio. Lastly, second-period rainfall occurs, and second-period profits are determined.

3.4. Tests for adaptation

We now derive tests to determine whether farmers update their rainfall expectations in response to past rainfall and whether they adapt their agricultural decisions accordingly. We lack data on farmer rainfall expectations, but the structure of the model allows us to test for adaptation, even without explicit data on expectations. To clarify the analysis, we introduce the following notation. Let $\mu_{1}=E_{0}(r_{1})$ and $\mu_{2}=E_{1}(r_{2})$ denote rainfall expectations. Let $w_{2}^{*}$ denote the optimal amount of wealth to bring into second-period wealth. Let $i_{2}^{*}$ and $\rho_{2}^{*}$ denote the optimal second-period irrigation and crop choice decisions. Note that $i_{2}^{*}$ and $\rho_{2}^{*}$ depend solely on μ₂ and $w_{2}^{*}$ . Furthermore, $w_{2}^{*}$ itself is a function of w ₁, μ₁, r ₁ and μ₂.

3.4.1. Tests for irrigation adaptation

To derive a test for irrigation adaptation, we take the derivative of second-period irrigation with respect to first-period rainfall. Rearranging terms, we get:

$${di_{2}^{*}\over dr_{1}}=\underbrace{{\partial i_{2}^{*}\over \partial w_{2}}{\partial w_{2}^{*}\over \partial r_{1}}}_{{\rm wealth}\, {\rm effect}}+ \underbrace{ \left[{\partial i_{2}^{*}\over \partial w_{2}}{\partial w_{2}^{*}\over \partial \mu_2}+{\partial i_{2}^{*}\over \partial \mu_2}\right] }_{{\rm expectations}\, {\rm effect}} {d\mu_2\over dr_{1}}.$$

The wealth effect term captures the impact that first-period rainfall has on second-period irrigation investment that occurs strictly via the impact of first-period rainfall on second-period wealth. The expectations effect term captures the impact that first-period rainfall has on second-period irrigation investment that occurs due to farmers updating their expectations of second-period rainfall. In online appendix 7, it is demonstrated that, for irrigation, the wealth effect is positive, and the expectations effect is negative.Footnote ⁷ Having separated the influences of wealth and expectations, two tests for irrigation adaptation are presented.

Proposition 3.1

If farmers increase their irrigation investment after low rainfall, this demonstrates adaptation: ${di_{2}^{*}\over dr_{1}}\lt 0$ implies ${d\mu_{2}\over dr_{1}} \gt 0$ .

Proposition 3.2

If, conditional on wealth, farmers increase their irrigation investment after low rainfall, this also demonstrates adaptation: $\left. {di_{2}^{*}\over dr_{1}} \right|_{w_{2}=constant} \lt 0$ implies ${d\mu_{2}\over dr_{1}} \gt 0.$

Proposition 3.1 is an unconditional test that can be used even without data on wealth. Proposition 3.2, on the other hand, requires data on wealth but is a more powerful test than Proposition 3.1. If farmers are adapting, but the wealth effect dominates the expectation effect, then Proposition 3.2 will detect adaptation but Proposition 3.1 will not.

3.4.2. Test for crop adaptation

Lastly, we derive a test for crop adaptation. We take the derivative of the second-period drought-tolerant crop area with respect to first-period rainfall. Rearranging terms, we get:

$${d\rho_{2}^{*}\over dr_{1}}= \underbrace{{\partial \rho_{2}^{*}\over \partial w_{2}}{\partial w_{2}^{*}\over \partial r_{1}}}_{{\rm wealth} \ {\rm effect}} + \underbrace{ \left[{\partial \rho_{2}^{*}\over \partial w_{2}}{\partial w_{2}^{*}\over \partial \mu_2}+{\partial \rho_{2}^{*}\over \partial \mu_2}\right] }_{{\rm expectations} \ {\rm effect}} {d\mu_2\over dr_{1}.}$$

The wealth effect term captures the impact that first-period rainfall has on second-period crop choice that occurs strictly via the impact of first-period rainfall on second-period wealth. The expectations effect term captures the impact that first-period rainfall has on second-period crop choice that occurs due to farmers updating their expectations of second-period rainfall. In online appendix 7, it is demonstrated that, for crop choice, the wealth effect is negative and the sign of the expectation effect is ambiguous. Therefore, it is not possible to test for crop adaptation without controlling for wealth. Without a wealth control, a negative correlation between lagged rainfall and drought-tolerant crop areas could be occurring solely through a wealth channel and, hence, would not provide evidence of adaptation. On the other hand, if wealth is held constant, this removes the wealth effect and makes the sign of the expectations effect unambiguously negative, thereby generating the following test for adaptation:

Proposition 3.3

If, conditional on wealth, farmers plant a greater area of drought-tolerant crops after low rainfall, this demonstrates adaptation to climate: $\left. {d\rho_{2}^{*}\over dr_{1}} \right|_{w_{2}=constant} \lt 0$ , then ${d\mu_{2}\over dr_{1}} \gt 0.$

4. Data sources and summary statistics

We test our model with two agricultural data sets: a household panel and a district panel. The household panel–the Rural Economic and Demographic Survey (REDS)–was collected by the National Council of Applied Economic Research (NCAER). The data cover three rounds (1970/71, 1981/82 and 1998/99) and 259 villages across the 17 major states of India. The second and third rounds of the survey include data on the original households and households that split off from the original households, as well as a sample of new households. The analysis is restricted to households that either were surveyed in multiple rounds or split off from a previously surveyed household. Online appendix 2 displays a map with the locations of the REDS villages and gives more information on the sampling. Online appendix 3 discusses attrition in the REDS data set and its implications for our study. The REDS survey includes detailed data on irrigation, crop areas, assets, wealth, profits and inherited assets.

The district panel–the India Agriculture and Climate Data Set–was compiled by a World Bank research group and covers 271 districts across 14 states for each year between 1956 and 1987 (Sanghi et al. Reference Sanghi, Kumar and McKinsey1998). Online appendix 3 includes a map of the districts covered in the World Bank data set. The data set includes information on irrigated areas, crop areas, crop yields and prices, but does not include information about assets, wealth or profits.

Panel A in table 1 presents the summary statistics for agricultural variables of both data sets. For households, agricultural profits per acre are measured as crop receipts minus crop expenses, divided by the area of land cultivated. For the district data set, which lacks information on crop expenses, crop revenue per acre of land cultivated is used. For households, a dummy variable is created for irrigation investment that is equal to one if the household purchased materials, hired labor or used family labor to construct new irrigation assets, purchase new irrigation assets or improve existing irrigation assets during the 12 months prior to the survey interview. For the district data set, which lacks direct information on irrigation investment, irrigation investment is defined as the log of the 1-year change in the area of irrigated land. For households, wealth is measured as the sum of the value of irrigation assets, farm equipment, livestock, non-farm assets, housing, durable goods, farm inventory and financial assets minus debts, deflated to 1971 rupees. Online appendix 2 gives additional details about the construction of the agricultural variables.

Table 1. Summary statistics

Notes: The table displays mean coefficients, with standard deviations in parentheses. The household sample is restricted to farmers who cultivate land. See section 4 for details as to how the variables are constructed.

For both data sets, the water need of a crop portfolio is measured as the area-weighted average of the crop water need of the crops grown in a given year. We use the daily crop water need values (in centimeters per day) provided on the Agriinfo.in, 2015 website. These values, which are specific to the way that crops are grown in India, are presented in table 2. These numbers represent the average daily amount of water each crop needs, over the course of its growing season, in order to achieve optimal growth. An important caveat is that these values refer to optimal amounts, not necessarily what farmers apply in practice.

Table 2. Daily water requirements of common crops grown in India

Notes: The daily water requirement is measured in centimeters per day. Monsoon crops are crops who are grown during the summer monsoon season.

Sources: Agriinfo.in, 2015.

There are two main growing seasons in India: the kharif (or monsoon) season, which is the primary growing season and runs roughly from June to September, and the rabi (or winter) season, which is secondary and runs from October through February. The bulk of the rainfall comes during the monsoon season, but both kharif and rabi crops are affected by the quantity of monsoon rainfall. Rabi crops are affected because the monsoon affects soil moisture levels over the winter months, as well as surface water and groundwater supplies that are used to irrigate some winter crops. To address this seasonality, two different measures of crop water need are used: one that includes all crops grown during the year, and an alternate version that only includes the crops grown during the monsoon season. This captures the fact that monsoon crops are likely to be more strongly affected by monsoon rainfall than non-monsoon season crops. Due to the lack of season-specific crop planting data, crops are classified based on the season in which they are typically grown. The monsoon crops are cotton, maize, millet, peanut, pulses, rice, sorghum, soybean and sugarcane and the non-monsoon season crops are barley, mustard, oilseeds, potato and wheat.

The agricultural data is merged with gridded weather data from the Terrestrial Precipitation: Monthly Time Series (1900–2008), version 2.01, and the companion Terrestrial Air Temperature data set. The weather data for each 0.5-degree latitude–longitude grid point combines information from 20 nearby weather stations, using an interpolation algorithm based on the spherical version of Shepard's distance-weighting method. Current year growing season rainfall is measured as the z-score deviation from that location's historical mean.Footnote ⁸

To capture the decadal variability of the monsoon, a decadal rainfall variable is created that is the simple average of the rainfall z-scores from the past decade. We also use a specification where we measure lagged rainfall as the number of especially wet or dry years over the past decade. Following Jayachandran, Reference Jayachandran2006, the 20th percentile is used as the cutoff for a dry year and the 80th percentile as the cutoff for a wet year. Panel B of table 1 gives the means and standard deviations for the rainfall variables for the relevant years of the household and district surveys. Online appendix 2 gives additional details about the construction of the weather variables and online appendix 4 presents a detailed discussion of the variation of the decadal rainfall variables.

5. Empirical strategy

5.1. Tests for irrigation adaptation

In order to test for irrigation adaptation, we analyze how irrigation investment responds to lagged rainfall. For the household data set, a regression is run of the form

(5) $${irr}\_{inv}_{ijt}= \alpha_{1}{decaderain}_{jt}+\alpha_{2}{rain}_{jt}+ \alpha_{3}{rain}_{jt-1}+ \lambda_{t} + \mu_{ij}+\zeta_{ijt},$$

where the subscripts represent household i, village j, and year t. The dependent variable irr_inv _ijt is a dummy variable equal to 1 if, during the recall period, a household purchased irrigation equipment or used labor to improve irrigation assets. The explanatory variables are past decade rainfall $decaderain_{jt}$ , current year rainfall rain _jt , one-year lagged rainfall rain _jt−1, a year fixed effect λ _t , a household fixed effect μ _ij , and an error term ζ _ijt .Footnote ⁹ The household survey follows households after household splits and after changes of the household head. Therefore, our household fixed effect is common to all parts of the household dynasty that have broken off from the original surveyed household, and can be thought of as a dynasty fixed effect.

decaderain _jt is measured in two ways. The first measure is a simple average of the rainfall z-scores from the past decade. The second measure tabulates the proportion of years in the past decade that were especially wet or dry. Following Jayachandran, Reference Jayachandran2006, the 20th percentile is used as the cut-off for a dry year and the 80th percentile as the cut-off for a wet year. The coefficient of interest is α₁. Our model demonstrates that the sign of α₁ is ambiguous and must be determined empirically. If the wealth effect dominates, then α₁ will be positive. Irrigation investment will increase after wet decades, due to an accumulation of wealth and increased investment in all assets. On the other hand, if farmers are adapting to expected rainfall and the size of this effect is larger than the wealth effect, then we will find α₁<0. Irrigation investment will increase after dry decades, due to farmers expecting more dry years in the future. Thus, finding α₁<0 provides evidence of adaptation.Footnote ¹⁰

Current year rainfall is controlled for because farmers can invest in irrigation at any time during the year. Thus, a farmer's observation of current year rainfall (based on, say, the first half of the growing season) might directly affect his decision to invest in irrigation during that period. This response would not indicate adaptation to expected future year rainfall, but would simply reveal within-season adjustment to current year rainfall.Footnote ¹¹

Propositions 3.1 and 3.2 demonstrate that we can test for irrigation adaptation with or without a wealth control. Thus, for completeness, we run a second household specification where we control for wealth. Once we have isolated the wealth effect, our model predicts that α₁=0 if farmers are not adapting. On the other hand, if farmers are adapting, then α₁<0.

Despite the dynasty fixed effect, there are two potential sources of endogeneity for wealth _ijt . First, if the current period's productivity shocks are correlated with lagged productivity shocks, then wealth will be endogenous (because lagged productivity shocks affect wealth). Secondly, as above, if there is variation in farming ability within a dynasty, and farming ability is correlated (within the dynasty) with wealth, this will also cause endogeneity.

We employ an instrumental variables strategy that attempts to mitigate these endogeneity concerns. The REDS survey contains information, for each household and split-off household, about the amounts of wealth, land and irrigated land that were inherited at the time of household formation. Typically in India, at the time of a father's death, each son in the household will inherit land and become head of his own separate household (Fernando, Reference Fernando2014). We instrument for wealth _ijt with $inhwealth_{ijt}$ , the amount of inherited wealth. Earlier work has used the same instrumental variables strategy (Foster and Rosenzweig, Reference Foster and Rosenzweig1995, Reference Foster and Rosenzweig2001; Reference Foster and Rosenzweig2010).

Due to household splits, many dynasties include multiple household heads, which gives us variation in $inhwealth_{ijt}$ , even in the presence of the dynasty fixed effect.Footnote ¹² We now discuss the exclusion restriction for our instruments and the extent to which these instruments reduce the endogeneity issues outlined above. First, consider the endogeneity that arises due to transient, current-period productivity shocks (that are not due to unobserved farmer ability). Because inheritances occurred in an earlier period, we should expect that inherited wealth should be less correlated with transient current period productivity shocks than current period wealth. Thus, we should expect the instruments to significantly reduce this source of endogeneity bias.

Secondly, consider the endogeneity that arises due to variations in farmer ability within a dynasty. Relative to this source of endogeneity, there is potential concern about whether the exclusion restriction holds. For example, if a son with higher farming ability inherits more wealth, then the exclusion restriction would be violated. However, there is evidence that inheritances may not be strongly correlated with variations in sons’ ability (Foster and Rosenzweig Reference Foster and Rosenzweig2002; Fernando, Reference Fernando2014),. Fernando, Reference Fernando2014 finds that the amount of inherited land is very strongly dictated by the number of sons in the family (and the total amount of land), and states that ‘equal division amongst sons [at the time of a father's death] is the norm’. If land is evenly divided, this is suggestive that non-land inheritances may also be divided roughly evenly. Note that even if there is purely equal division of inheritances among sons, changes across generations of household heads provide variation of the inheritances within each dynasty.

We cannot fully prove that contemporaneous variations in inheritances are uncorrelated with unobserved household ability, but to the extent that these inheritances are less correlated than current wealth and current irrigated land, our instrumental variables strategy should at least reduce the endogeneity bias. Due to potential concerns about the validity of the instrument, a non-instrumented version of the regression is run in online appendix 6.

For the district regression, irr_inv _jt is defined as the log of the one-year change in the district's irrigated area, we use a district fixed effect, and we do not control for wealth. Proposition 3.1 demonstrates that we can test for irrigation adaptation, even in the absence of a wealth control. As with the household regression, finding α₁<0 provides evidence of adaptation.

5.2. Test for crop adaptation

Lastly, we test for crop adaptation. We only perform this test with our household data set, and our regression is of the form:

(6) $$\eqalign{{water}\_{need}_{ijt} &= \gamma_{1}{decaderain}_{jt}+\gamma_{2}rain_{jt} +\gamma_{3}{rain}_{jt-1}+\gamma_4{wealth}_{ijt} \cr & \quad + \tau_{t}+ \phi_{ij}+\psi_{ijt} }$$

where water_need _ijt is the area-weighted water need of the farmer's crop portfolio. In one specification, we look at the area-weighted water need of all crops grown during the year. In a second specification, we look at the area-weighted water need of monsoon-season crops only. As mentioned above, we control for current year rainfall because farmers may have some knowledge of the current year's rainfall before they sow all of their crops. As in the irrigation regression, a response of crop choice to current year rainfall would indicate a within-season adjustment to rainfall, but would not provide evidence of adaptation to the expected future year rainfall.Footnote ¹³

We control for wealth _ijt because, as demonstrated in section 3.4.2, without a control for wealth _ijt , we could not interpret γ₁ as evidence of adaptation. Wealth is endogenous and we instrument for it with inherited wealth. The validity of the instrument follows the same argument as above. Due to potential concerns about the validity of the instrument, we also run a non-instrumented version of the equation in online appendix 6. Finding γ₁=0 demonstrates that farmers are not adapting their crop portfolios. Conversely, in the presence of adaptation, we expect to find γ₁>0.

7. Robustness

In online appendix 6, we investigate the robustness of our results.

First, we re-run our adaptation regressions using a fixed-effects specification that drops our instrumental variables strategy. In light of potential issues with our instruments, these results provide another set of estimates which may be of interest. In addition, using the non-IV specification allows us to estimate a new set of standard errors that allow for spatial correlation. This is important because, as indicated in online appendix 4, our lagged rainfall variable demonstrates significant spatial correlation. To implement these standard errors, we use code from Hsiang and Solow, (Reference Hsiang and Solow2010) and Fetzer, (Reference Fetzer2014). Guided by the autocorrelograms in online appendix 4, we allow for a correlation within 800 km using a Bartlett (triangular) kernel. The results are robust to these changes.

Secondly, we re-estimate our regressions using rainfall lag windows of 5 or 15 years, to verify that the choice of a 10-year window is not driving the results. The district irrigation regressions and the household crop regressions are robust to using alternate rainfall windows. In the household irrigation regressions, however, the signs of the coefficients of interest are preserved but are no longer statistically significant. We also present regressions in which we control for lagged rainfall separately for each year (rather than as an average). In this case, the coefficients are no longer individually statistically significant (likely because they are correlated with each other), but the set of rainfall lags is jointly significant.

Thirdly, we analyze how irrigation investment and crop choice are affected by lagged temperature shocks from the past decade. Temperature shocks affect profits and wealth. Therefore, we would expect to see wealth effects from lagged temperature on irrigation investment and crop choice. However, temperature does not undergo the persistent cycles that precipitation undergoes. Therefore, we would not expect to see an expectations effect for temperature. Our analysis corroborates this story: we find evidence of a temperature-induced wealth effect, but no evidence of a temperature-induced expectations effect.

Fourthly, we discuss the possibility that depletion of groundwater or surface water might be causing the relationship between irrigation investment and lagged rainfall that we have found. Using irrigated area (rather than irrigation investment) as the dependent variable, we find that the area of irrigated land increases after dry decades. As is discussed in greater detail in the appendix, this test provides some reassurance that water depletion is not driving the results, but it does not fully rule out that possibility.

Fifthly, we test whether the irrigation adaptation results might be due to public (government) investments rather than private (farmer) investments. In India, the bulk of direct public irrigation investments are large-scale dams. When we control for the presence of these dams, the irrigation adaptation results are preserved. However, government irrigation investment is an outcome variable and may be endogenous to the household investment decision. For this reason, our results are suggestive that the adaptation results are not driven by public investment, but do not definitively rule out that possibility.

Sixthly, we test whether changes in agricultural technology or policies might be confounding our results. We add controls for high-yielding variety crops, electrification rates, fertilizer prices, financial institutions, agricultural extension services, transportation infrastructure and government intervention in output markets. The irrigation and crop adaptation results are robust to adding these controls. However, these results are suggestive only, not definitive, since we are only able to control for a subset of possible confounders. Furthermore, the confounders that we do control for are potentially endogenous to the household irrigation and crop decisions.

Lastly, we run our regressions with region-by-year fixed effects. Due to the large-scale spatial correlation of the monsoons, it is possible that unobserved, time-varying confounding factors might be correlated with the lagged rainfall variables. Region-by-year fixed effects flexibly control for this. The district irrigation results and the household crop results are robust to the addition of these controls. The coefficients of interest are preserved in sign, magnitude and significance level. In the household irrigation regressions, however, the signs of the coefficients of interest are preserved but the magnitudes decrease by about 50 per cent and the coefficients are no longer statistically significant. The inclusion of region-by-year fixed effects is a stringent test since the household data set only spans three survey years. Therefore it is perhaps unsurprising that our household irrigation regressions are only weakly robust to the inclusion of these controls.

8. Effectiveness of adaptation

The preceding text finds evidence of adaptation; we now quantify its efficacy. What fraction of profits were farmers able to protect from adverse climate variations? To answer this question, we use the household data set to estimate the extent to which irrigation adaptation increased profits during 1971–1999.Footnote ¹⁷ Rainfall during this period was below average (as shown in figure 1), which reduced profits. On the other hand, farmers adapted to this below-average rainfall, by increasing their irrigation investments, which should have partially offset profit losses.

We take a two-step approach to estimate the efficacy of adaptation. First, we estimate the percentage of profits that were lost due to below-average rainfall during 1971–1999. Next, we estimate the percentage of these losses that were recovered due to increased irrigation investment. To calculate these percentage changes, we estimate profits π from three scenarios: a counterfactual scenario A, in which the drought did not occur; a counterfactual scenario B, in which the drought occurred but farmers did not adapt their irrigation; and the actual scenario C, in which the drought occurred and farmers adapted. The percentage of profits lost due to the below-average rainfall is ${\pi^{B}-\pi^{A}\over \pi^{A}}$ . The percentage of lost profits that were recovered by adaptation is ${\pi^{C}-\pi^{B}\over \pi^{B}-\pi^{A}}$ .

We observe π ^C only in the survey years (1971, 1982 and 1999). To estimate π ^C for the non-survey years, we regress survey-year profits on survey-year rainfall, temperature, irrigation and wealth:

(7) $$\eqalign{\pi_{ijt} &= \Sigma \beta_{1q}\times ({rain}_{jt}=q) + \beta_{2}{propirr}_{ijt}+ \Sigma \beta_{3q}\times ({rain}_{jt}=q) * {propirr}_{ijt} \cr & \quad + \beta_{4}{wealth}_{ijt}+\beta_{5}{temperature}_{jt} +\delta_{t}+\kappa_{ij}+\epsilon_{ijt}. }$$

The variable rain _jt =1,2,3,4,5 is a categorical variable representing the rainfall quintile for village j in year t and ${rain}_{jt}=3$ is the omitted category. The results of this regression are shown in table A2 of online appendix 5. We use the estimated coefficients and fixed effects to estimate non-survey-year profits:

(8) $$\eqalign{\pi^C_{ijt}& = \Sigma \beta_{1q}\times ({rain}_{jt}=q) + \beta_{2}\overline{{propirr}_{ijt}}+ \Sigma \beta_{3q}\times ({rain}_{jt}=q) * \overline{{propirr}_{ijt}} \cr & \quad + \beta_{4}\overline{{wealth}_{{ijt}}} + \beta_{5}{temperature}_{jt}+\overline{\delta_{t}}+\kappa_{ij},}$$

where $\overline{{propirr}_{ijt}}$ , $\overline{{wealth}_{ijt}}$ and $\overline{\delta_{t}}$ are linearly interpolated between survey rounds.

To estimate π ^B , we compute $\widehat{{propirr}_{ijt}}$ , a counterfactual value of the proportion of irrigated land in the absence of adaptation. We use the coefficients from column 2 of table A10 in online appendix 6 to calculate the adaptive response of irrigation to lagged rainfall.Footnote ¹⁸ This table is analogous to the baseline irrigation adaptation specification (table 3) but uses the proportion of irrigated land as the dependent variable, rather than an irrigation investment dummy. The irrigation investment dummy captures precisely how the household is adjusting its irrigation this year. However, using it requires knowing what fraction of the farmer's land becomes irrigated when he invests in irrigation, since profits depend on the proportion of land irrigated. Thus, we instead use the proportion of irrigation, which is a coarser measure of adaptation. We use this regression to subtract a quantity of ‘adapted irrigation’ from $\overline{{propirr}_{ijt}}$ , which gives us $\widehat{{propirr}_{ijt}}$ , i.e., what irrigation would have been in the absence of adaptation.Footnote ¹⁹ We estimate

(9) $$\eqalign{\pi^B_ijt &= \Sigma \beta_{1q}\times (rain_{jt}=q) + \beta_{2}\widehat{propirr_{ijt}}+ \Sigma \beta_{3q}\times (rain_{jt}=q)*\widehat{propirr_{ijt}} \cr & \quad + \beta_{4}\overline{wealth_{ijt}} + \beta_{5}temperature_{jt}+\overline{\delta_{t}}+\kappa_{ij}.}$$

Lastly, to estimate π ^A , we calculate expected annual profits, using a 20 per cent chance of each rainfall quintile occurring. This calculation projects what expected profits would have been if rainfall were at its historical mean distribution. We estimate

(10) $$\eqalign{\pi^A_ijt &= \Sigma \beta_{1q}\times (0.2) + \beta_{2}\widehat{propirr_{ijt}}+ \Sigma \beta_{3q}\times (0.2) * \widehat{propirr_{ijt}} \cr & \quad + \beta_{4}\overline{wealth_{ijt}} + \beta_{5}{temperature}_{jt}+\overline{\delta_{t}}+\kappa_{ij}.}$$

We use π ^A , π ^B and π ^C to calculate profit losses and recoveries. For each farmer, we sum total profits during 1971–1999, under each scenario. Using these profit estimates, we find that, on net, the dry regime decreased profits by 0.3 per cent. However, there is substantial heterogeneity and, for households with losses, the average loss was 7.9 per cent. We estimate that farmers with losses recovered, on average, only 9.4 per cent of their losses. Note that this estimate is an upper bound on the effectiveness of irrigation adaptation, because it does not incorporate the cost of the irrigation investments.

Our results demonstrate that farmer adaptation to persistent rainfall deviations was of limited efficacy. This suggests that adaptation to anthropogenic climate change may also be limited. However, there are four caveats to note. First, we only analyze irrigation adaptation. Farmers are likely to adapt via other channels as well, which will allow them to recapture additional profits. Secondly, extrapolating our results directly to future climate change is problematic, since future climate change will affect both rainfall and temperature. Thirdly, in addition to changing the demand for irrigation water, climate change will also affect the supply of irrigation water (Zaveri et al., Reference Zaveri, Grogan, Fisher-Vanden, Frolking, Lammers, Wrenn, Prusevich and Nicholas2016). In some regions, the available supply of irrigation water will decrease, potentially limiting the ability of farmers to increase their irrigation. Lastly, rich farmers with above-average land areas are over-represented in our sample. However, if we expect wealthier households to adapt more easily than poor households, then our estimate would overstate the efficacy of irrigation adaptation. Our results indicate that, even among richer households, irrigation adaptation was of limited benefit.