2.1. PROGAN: description and data

PROGAN is a national livestock subsidy that began accepting applications in waves, starting in 2003, with a second wave in 2008 and a third in 2014.Footnote ⁴ According to Álvarez-Macías and Santos-Chávez (Reference Álvarez-Macías and Santos-Chávez2019), the program was inspired by the idea of conditional cash transfers, popular in Mexico due to the rollout of Progresa (an educational conditional cash transfer program) in 1997. The goal of the initial wave (2003–2006) was to improve the productivity of extensive cattle production, and for this reason it was focused in tropical, arid and semi-arid zones where this activity generally occurs. Program managers intended to give applicants yearly payments for the entire duration of the wave after enrollment for the number of animals they owned at the moment of the application. However, payments were unexpectedly disrupted during the first wave, so producers only received payments for four out of five years between 2003 and 2007, and the timing of these varied considerably.

During the second and third waves of the program (2008–2013, and 2014 onwards), the focus was on expanding program coverage to include a broader set of areas and types of production beyond cattle, and on increasing the sustainability of this production. Further, the program required improving vegetation cover and increasing fodder production within their land, although the monitoring of these rules and definitions lacked clarity and guidance (more details included in online appendix A).

To broaden the program, they tried to expand the reach to smaller livestock producers by offering them larger payments starting in 2008. During the first wave, PROGAN subsidized only cattle while the second and third waves added subsidies for dairy cows, sheep, goats, and bees. The second and third waves also required commitments to environmental management activities and technical assistance to implement them. However, in practice the support for and monitoring of these commitments was extremely weak (Alvarez and Santos, Reference Alvarez and Santos2013). In section 2.6, we examine the changing composition of enrollment over the waves included in our analysis. Table B4 (online appendix) summarizes the wave-specific variation in the livestock subsidy coming from changes in program rules and missed payments.

Data on PROGAN enrollment and payments from 2003 to 2015 comes from SAGARPA (Ministry of Agricultural, Livestock, Rural Development, Fish and Food). We use a GDP deflator (World Bank, 2017) to transform monetary values in 2008 real Mexican pesos (MXN). Although the subsidy is available at the individual landowner level, we can not match them to parcels, thus we aggregate them to the municipal level.

Our analysis is focused on livestock (we exclude bee subsidies). Ranchers receive the yearly subsidy as a function of the cattle unit equivalent (referred to as “animal equivalents”), which varies according to the type of animal (e.g., one goat is equivalent to one sixth of a cow, and consequently, the subsidy amount for one goat is one sixth of the amount for a cow) and by a metric called “the pasture coefficient,” which measures how many animals a hectare of land can support in a sustainable way. Subsidy amounts are restricted by the pasture coefficient and calculated using the information provided in the National Livestock Registry. We calculate the maximum sustainable livestock for each municipality by tying the calculations for the pasture coefficient to characteristics of the land specific to each municipality (details presented in online appendix B). Total allowed number of cattle unit equivalent subsidized are high and so large ranchers receive a significant portion of the total subsidy.Footnote ⁵ Beyond being given to existing livestock holders and the limitation on subsidies above the amount dictated by the pasture coefficient, PROGAN had no other targeting criteria or conditionalities. It therefore operated as a cash transfer to individuals holding livestock.

During the first wave, the subsidy per animal increased by 100 nominal pesos each year (figure 1a). In 2007, there was no subsidy per animal because this is the unplanned additional year of the first wave. In 2008, the subsidy per equivalent animal dropped by 50 per cent overall, although it started to include a premium for small producers. In 2011, the subsidy represented about 5 per cent of the average value of a cow at the slaughterhouse (SIAP, 2021). Since cattle are typically ready to slaughter after at least 24 months, the subsidy represented on average about 10 per cent of its commercial value at the slaughterhouse (Skidmore et al., Reference Skidmore, Sims, Rausch and Gibbs2022). Figure 1c graphs the expected nominal subsidy strictly calculated according to the program rules and compares it with the aggregated payments that were received by producers. Since the first wave was originally planned to occur between 2003 and 2006, with unit payment increasing each year, there is a steep increase in the expected subsidy during those years. The comparison between the expected nominal and the real subsidy reveals two key points. First, the large variation in the real PROGAN subsidy in 2007 results from a combination of increases in payment steps and delayed payments from the beginning of the first wave that were given in later years. Second, the greater variation in the subsidy per animal and uncertainty about timing of payments suggests that the first wave contains more exogenous variation than subsequent waves. Because of this, we implement robustness checks that use only the first wave.

Figure 1.

Nominal and real subsidy per equivalent animal in panel (a), variation in equivalent animals enrolled in panel (b), and PROGAN subsidies in panel (c). Vertical lines represent application years for PROGAN (i.e., 2003, 2008, 2014). The grey shadowed area represents the unplanned additional year of the first wave.

Variation over time in the amount of PROGAN subsidies comes from four sources: changes in (1) the subsidy per animal determined by the program, which varies within enrollment waves; (2) the timing of payments, some of which were unexpected; (3) animals enrolled in 2003, 2008, and 2014 (which varies according to the type of animals eligible and maximum allowed), and (4) the real value of the peso. While the variation from (1), (2), and (4) is arguably exogenous to individual farmer actions, (3) presents identification challenges which we will discuss further below. Figure 1 shows these sources of variation in the livestock subsidy: figure 1a presents (1) and (4); figure 1b presents (3), and figure 1c presents the aggregated subsidy which includes all four sources of variation. The treatment variable we use throughout this analysis is depicted by the thick line in figure 1c.

The number of equivalent animals enrolled in PROGAN is about 5.7 million during the first wave (figure 1b). This initial enrollment occurred in nearly 68 per cent of the municipalities in our sample. Equivalent animals increased by almost 88 per cent for the second wave, with 22 per cent of municipalities enrolling for the first time, and a large part of the increase was due to increases in livestock number in the first wave municipalities (figure B6, online appendix). In 2014, the number of equivalent animals decreased by 17 per cent, with new enrollment in only 3 per cent of municipalities. According to conversations with program managers, this is most likely due to a stronger enforcement of the maximum capacity of the land as dictated by the pasture coefficient. Seven per cent of municipalities never had any enrollment in PROGAN.

2.2. PES: description and data

Mexico's PES program, like PROGAN, began in 2003 with a program of payments for hydrological services. Application is voluntary, and payments are only awarded to applicants within eligible zones defined by the government. Eligible zones are determined by geographic characteristics chosen by the federal government and vary year to year. The amount of the subsidy depends on forest type and the government estimates of deforestation risk, and has evolved over time (see online appendix table A2), with decreases in its real value driven by inflation. We examine the arms of the PES program that focus on hydrological services and biodiversity, which are the largest and most durable.Footnote ⁶ Initially, targeting was based almost entirely on eligible zones and existence of forest cover, with properties having higher forest cover receiving priority. Starting in 2006, a point system was implemented to allocate the subsidies to the applicants. Scores are calculated according to a number of criteria that have also evolved over time, such as deforestation risk; surface water scarcity; indicators about whether the property falls in an over-exploited aquifer, a Natural Protected Area, or a municipality with majority indigenous population or with high poverty; and other factors. Applicants with the highest scores are approved until the state budget limit is reached. This means that the threshold of points for acceptance into the program varies by state-year, and by sub-program within state-year. Participants sign a five-year contract, during which payments are conditional upon forest preservation and improvements in forest management (e.g., building fire breaks). Monitoring is done via satellite imagery and follow-up live inspection in the case of suspected violations. Payments are revoked or reduced in the event of contract violations. The evolution of program targeting is discussed in detail in Sims et al. (Reference Sims, Alix-Garcia, Shapiro-Garza, Fine, Radeloff, Aronson and Yañez-Pagans2014) and Alix-Garcia et al. (Reference Alix-Garcia, Sims and Phaneuf2019).

Data for the federal PES comes from the agency managing the program, the Mexican National Forestry Commission (known by its Spanish acronym CONAFOR). CONAFOR provided digital maps of the parcels, which detail the location and boundaries for all land submitted to the program from 2003 to 2015. For our main analysis, this data is aggregated to the municipality level. An analysis at the parcel level is provided in online appendix F.

Our main treatment variable for the PES program is ratio of recipient hectares per municipal area. We use this rather than the monetary value of payments per municipality hectare because this measure is a more direct proxy for the contract that producers make regarding their deforestation behavior. However, this measure, unlike the treatment variable for PROGAN, does not change with the rate of inflation or the exchange rate. Any effects of the relative value of payments will already be realized in our enrollment levels measure. Figure B5 (online appendix) shows the delineation of the eligible zones over time for the PES program and the geographic distribution of the applicants accepted (in black) and rejected (in red). Accepted and rejected parcels tend to be near each other, and they are distributed evenly throughout the country and the eligible zones. Over time, the eligible zones have expanded considerably, so there is significant variation in the number of years in which specific land has been eligible.

The ratio of PES applicant hectares at the municipality level per eligible zone is an outcome of interest to measure whether PROGAN affected the willingness to apply in PES. To control for characteristics of eligible zones land that could confound the willingness to enroll in PES and PROGAN, we calculate the following for each municipality and year: per cent in common property, in natural pasture in 2002, in pasture associated with livestock production, as well as road density and the area of the zones. The National Institute of Statistics and Geography (INEGI) provides data on the baseline pasture (INEGI, n.d.-a) and the road network (INEGI, n.d.-b). The percentage within communal land is from the PHINA (n.d.). Because the zones change from year to year, these aggregates vary across time.

2.3. Sample

In all of our analysis, we restrict ourselves to municipalities that had at least 50 ha of measured forest cover in 2000 (the baseline year of our forest data). The reason for this is that our measure of environmental impact is deforestation, which cannot be detected if there is no measurable forest. We also restrict ourselves to municipalities that had at least 50 ha of eligible zones for the PES program on average over the sample period, although the online appendix shows results with a sample unrestricted by eligible zones. This is because we intend to measure the extent of the competition between agricultural and environmental subsidies. Although the PES program does pay for the conservation of arid ecosystems, many of these may not have forest as measured by our remotely sensed outcome. Because we cannot assess environmental impacts in these areas, we exclude them from our analysis. This restriction limits us to 2,166 municipalities out of the 2457 total municipalities in Mexico. Despite the continuous expansion of the eligible zones across the country, PES payments were only ever allocated in 887 municipalities during our study period.

2.4. Deforestation

To analyze the impact of the livestock subsidy on deforestation, we use tree cover loss information from 2001–2014 and forest cover metrics for 2000 from Hansen et al. (Reference Hansen, Potapov, Moore, Hancher, Turubanova, Tyukavina and Townshend2013) at the level of the PES parcels and the municipality.Footnote ⁷ An area is defined as forested in 2000 if its canopy cover was greater than 50 per cent, and deforestation is conditional on the area being forested in 2000.

To examine heterogeneity as well as to conduct program targeting analyses, we create a deforestation risk measure at the municipal level. We use a sample of nearly 80,000 $5 \,km \times 5\,{\rm km}$ grid cells created by the authors to predict the probability of deforestation using pre-program data (i.e., 2001–2002). Rather than choosing a set of variables to predict deforestation, we use machine learning. Specifically, we apply a probit lasso estimator, which relies on both regularized estimation and data-driven choices of the regularization parameter. It has an advantage over OLS for prediction in that it helps to minimize overfitting (Ahrens et al., Reference Ahrens, Hansen and Schaffer2018). The choice of a probit also ensures that the predicted value remains between 0 and 1, which is useful when the user is interested in the predicted probability, rather than the marginal effects of particular covariates. Covariates included are baseline forest cover, distance to city, road density, distance to nearest urban area, average and standard deviation of elevation, average and standard deviation of slope, biome indicators, and state indicators (estimation equation and results are presented in online appendix table B3). The deforestation risk measure is equal to the municipal average of the predicted probability of deforestation of each grid cell included in the municipality.

2.5. Livestock intensification outcome

To proxy for intensification of livestock production, we examine a measure of transition from non-fodder crops into fodder production. The planting of fodder crops allows producers to raise more animals on less land, and with proper choice of fodders can improve animal and pasture health, as well as reducing the carbon footprint of raising livestock (Ates et al., Reference Ates, Cicek, Bell, Norman, Mayberry, Kassam and Louhaichi2018). The increase of fodder use and productivity of livestock production was a major focus for PROGAN throughout its various waves (Álvarez-Macías and Santos-Chávez, Reference Álvarez-Macías and Santos-Chávez2019). The information on fodder crops comes from a government program called PROCAMPO, which began in 1994 as a reaction to the NAFTA agreement (Sadoulet et al., Reference Sadoulet, Davis and de Janvry2001).Footnote ⁸ This program subsidizes continuous agricultural production for around 3 million producers, or approximately 14 million hectares per year. Because additional enrollment in the program was forbidden after 1993 and subsidies do not vary by crop type, producer choice is limited to which crop to produce. If they cease planting, they lose the subsidy. To obtain data on replacement of crop with fodder for each municipality and year, we aggregate the area cultivated in alfalfa, fodders, yellow corn, fodder corn, annual pasture, and forage sorghum, and divide by the total subsidized hectares of the municipality in 1999, the first year of our data. PROCAMPO covered almost all of the agricultural area in 1994 and 58 per cent of the total agricultural area in 2002 (OECD, 2005). Although it is not a census, it does cover a large part of the agricultural activity in the country. Further, it provides a detailed panel on agricultural production that includes producers of all sizes and for all crops.

2.6. Descriptive statistics

Table B5 (online appendix) summarizes a number of key variables according to whether PROGAN enrollment was, on average, above or below the median across all municipalities. Total submitted hectares of PES are lower in areas with high PROGAN and, given the relatively similar percentage of hectares submitted within eligible zones in both types of municipalities, it would appear that the eligible zones are smaller in areas with high PROGAN. We also observe higher deforestation in high PROGAN municipalities, a smaller drop in deforestation over time in areas where PROGAN is more prevalent, and a greater deforestation risk in high PROGAN municipalities. Municipalities with low and high PROGAN intensity have similar baseline forest per municipal hectare. PROGAN tends to be higher in municipalities that have less dense population, lower slope and elevation, and also have greater replacement of crop with fodders.

Since the first wave provides a key robustness check to our analysis, we provide additional details about the randomness in payments occurring during this period. Table B6 (online appendix) shows when each of the four payments were provided over the five years. Only 40 per cent of total payments were allocated in the first year of the first wave as expected, with some producers even receiving their first payment in 2007. Overall, 5.1 per cent of the planned payments did not occur in the first wave, 7.6 per cent did not occur in the second wave, and 2.9 per cent additional payments occurred in the third wave (table B4, online appendix). When examining the spatial distribution of payments during the first wave (online appendix table B7), we show that no region benefited disproportionately from earlier payments. In sum, online appendix tables B6 and B7 show that the shifts in the timing of payments during the first wave are beyond the control of producers and occur without any particular spatial pattern.

Municipalities that enrolled in the first two waves had more potential for livestock production as measured by the average municipal pasture coefficient. This potential decreased substantially for the few municipalities that started enrollment in the third wave, and those that never received PROGAN also have relatively lower livestock potential (online appendix figures B7 and B8). Underlying deforestation risk is highest in municipalities that enrolled first, and drops significantly for those beginning in the second wave, increasing slightly for the third wave and never enrolled municipalities. We test statistically how characteristics change by cohort and intensity of enrollment (table B8, online appendix). Overall, municipalities with higher PROGAN enrollment are larger, at lower slope and elevation, with higher deforestation risk and greater potential for animal production. As enrollment progressed, smaller municipalities with somewhat lower deforestation risk and less livestock potential began to enroll.

These wave-specific summary statistics imply that comparisons that exploit the enrollment choice after the first wave may be biased upwards. However, when we limit analysis to the first wave, we observe similar results to the analysis using the entire sample, suggesting that this bias is unlikely to drive our results.

3.1. Empirical strategy

Because agricultural and forest productivity both depend on underlying characteristics of the land, identifying the effect of PROGAN on deforestation is challenging. However, under the assumptions that (1.1) the programmatic adjustments in payment levels, (1.2) the unexpected change in payment timing, and (1.3) fluctuations in the real value of the peso are all exogenous to characteristics of the land; and that (2) producers did not change their behavior in anticipation of enrollment years, we can approach the causal effect of the impact of changes in the value of the livestock subsidy on deforestation. The baseline estimation equation is:

(1)\begin{equation} Y_{mt} = \beta PROGAN_{mt} + M_m + \theta_t + u_{mt}, \end{equation}

where $Y_{mt}$ is the percentage deforestation over baseline forest cover for municipality m and $PROGAN_{mt}$ is the municipal livestock subsidy per hectare. We prefer this measure to the direct measure of PROGAN-funded animals per hectare because the claim for exogeneity is stronger. This amount changes annually, which allows us to examine subsets of the data where no enrollment decisions are being made, and where identification of changes over time comes only from the changes beyond the control of the individual producers. In online appendix tables C9 and C10, we show estimations using only PROGAN-funded livestock per hectare as the treatment metric.

Depending on the specification, $M_m$ is a state or a municipal fixed effect. The first controls for geographic variation across states and the second for time-invariant characteristics of the municipalities. $\theta _t$ are year fixed effects and standard errors $u_{mt}$ are clustered at the municipal level. In the fourth specification, we restrict the sample to municipalities that ever had PES enrollment; this sample supports comparability with the parcel level PES analysis, discussed in section 4. In the last specification, we apply the baseline forest area as a weight because these areas vary substantially from municipality to municipality.

The identification of $\beta$ comes from variation in PROGAN intensity within municipalities across time.Footnote ⁹ The implicit comparison is between municipalities with higher and lower PROGAN intensity. To examine the assumption that trends might be different in places where there was eventually high program enrollment in PROGAN, we apply two tests of differences in trends before 2003. First, we create categories based on the median level of payments over the full duration of the program. Second, we calculate the average of subsidy payments across all years. We interact these with the year trend for the two pre-program years. We observe no differential trends after conditioning on municipality and year fixed effects (online appendix table C1). Figure C1 (online appendix) shows these pretrends visually.

In the results section, we also discuss several robustness checks intended to probe these underlying assumptions, including whether the result is robust to using only the variation in payments caused by adjustments in program rules and changes in the value of the currency during the first wave (2003–2007), a test of anticipatory behavior using leaders, a falsification exercise based on randomizing the treatment multiple times, and analyses of robustness to additional controls.

3.3. Intensification of livestock production

These estimations demonstrate that the livestock subsidy increased deforestation when the amount of the payments increased. One possible mechanism to explain this effect is extensification. To examine this dynamic, we consider how the introduction of the livestock subsidy modified the crop choices within the long-standing PROCAMPO program. Specifically, we measure the impact of PROGAN on the per cent fodder cultivated on program land between 1999 and 2014. The logic is that planting fodder may allow more livestock to be supported on less land because fodder is of higher nutritional value than extensive pasture. We use a similar specification to equation (1), replacing the deforestation outcome with per cent fodder on PROCAMPO land. As above, the identifying assumption is that changes in PROGAN enrollment are uncorrelated with other factors driving crop choice within PROCAMPO. This is untestable, but we do not find any statistical difference in crop choices during pre-PROGAN years (1999–2002) (table D1, online appendix).

Table 2, specifications (1)–(3), show that PROGAN actually decreased the share of fodder on PROCAMPO land. Since there is large variation in PROCAMPO baseline area across municipalities, our preferred specification is in column (4), which contains area weights. We estimate a negative effect significant at the 10 per cent level associated with the subsidy. These findings are similar to the analysis restricted to the impact of PROGAN for 2003–2007 (table D2, online appendix).

Table 2.

Regressions of PROCAMPO fodder (%) on PROGAN intensity

Note: Years 1999–2014. Pre-mean of dependent variable is 1.3 %. Robust standard errors are clustered by municipality. The fourth column includes weights for the municipal area of PROCAMPO in 1999.

Further descriptive evidence that intensification did not occur as intended can be found in online appendix B. These figures show trends in average cattle weight over time using aggregated state data from the Service of Agri-food and Fishery Information (SIAP, 2021), in states with above versus below median levels of PROGAN enrollment. Cattle weight is a proxy for productivity, since increases in slaughter weight are associated with better feed and genetics (Terry et al., Reference Terry, Basarab, Guan and McAllister2021). The data show flat cattle weight in both high and low PROGAN states, with a simultaneous increase in 2014. We also do not observe differential trends across states in heads slaughtered, cattle price, or production. Trends for pork, a potential placebo, also show no differences across high and low PROGAN states, and exhibit similar time trends to cattle.

We therefore find no evidence that PROGAN increased intensification. There are two caveats to this. First, producers might be planting fodder on their own PROCAMPO plots and selling it to neighboring municipalities, so spillover effects might undermine identification. Second, producers may be intensifying in other ways, for example, by importing feed, improving livestock rotations, or planting fodder on non-PROCAMPO land. There are also other potential mechanisms that might drive the observed increase in deforestation. First, higher rents per hectare as a result of the program could induce land use change. A complementary dynamic might occur if the cash payments allowed producers to engage in production for which they did not have capital prior to the program. Finally, increases in income resulting from the program could result in deforestation via increased consumption of land-intensive goods. We thus take this evidence as suggestive.

4.1. Program growth and competition

Enrollment in PROGAN and PES increased substantially over our study period. The quantity of subsidies paid out to PROGAN participants dwarfs those paid for PES. The programs have less overlap in some areas than in others. Figures 2a,b compare PES applications and payments to PROGAN in municipalities with below and above median PROGAN participation. In municipalities with low PROGAN participation, PES payments increase more over time, whereas in those with high PROGAN participation, PES payments are relatively lower. Further, online appendix table B5 shows that the average area enrolled in PES is nearly twice as high in low PROGAN municipalities.

Figure 2.

Total payments for PROGAN, total payments for PES, and area of land applying for PES. Vertical lines represent application years for PROGAN (i.e., 2003, 2008, 2014). Municipalities with below median levels of PROGAN are in panel (a), and above median municipalities in panel (b).

Figure A1 (online appendix) shows the geographic intensity of the PROGAN subsidy in 2008 and all PES recipients over the course of our study. While many PES recipients are located in low PROGAN municipalities in the center of the country, the map shows big overlaps, particularly in coastal municipalities. There is also evidence that these two programs operate within the very same beneficiary household or community. A 2016 survey of over 850 PES applicants between 2011 and 2014 (Alix-Garcia et al., Reference Alix-Garcia, Sims and Phaneuf2019) found that 36 per cent of livestock-owning households in villages that had applied for PES had received a payment from PROGAN in the previous year. Therefore, although we observe that municipalities with lower PROGAN tend to have higher PES, there are still geographies with considerable presence of both programs. The next section examines more rigorously whether there is substitution in enrollments.

4.2. Enrollment effects

If PROGAN decreases enrollment in PES, then it may indirectly reduce the amount of deforestation the program is able to avoid. This section examines the effect of the livestock subsidy on willingness to enroll in PES between 2004 and 2015. The dependent variable is the total number of hectares that apply to the PES program divided by the total hectares in eligible zones for each given year. We include characteristics within PES eligible zones to control for changes in the quality of land available for PES participation.

Generally speaking, the results presented in table 3 show that there is no statistically significant impact of PROGAN on PES enrollment, regardless of the level of controls and specification. The point estimates are large, so we cannot rule out all levels of enrollment effects. Bias might enter into the estimation through simultaneity or because there is an omitted variable driving changes in the willingness to enroll in PES that is correlated with the choice of the number of animals to enroll during the allowable enrollment years. The latter is less likely with municipal fixed effects, but might occur if there are trends, such as technological change, that drive investment in livestock differentially across municipalities with higher and lower PROGAN enrollment. To address the issue of strategically increasing herd size prior to the year of enrollment, we include estimates with leads (table E1, online appendix). Although there are some specifications that indicate weakly significant simultaneous impacts, they are are not consistent, and the sum of the lead and contemporaneous terms are small and not statistically different from zero. We also run a regression with a balanced panel where the dependent variable is the percentage of municipal area submitted to PES (table E2, online appendix). To exploit only the exogenous variation in PROGAN stemming from programmatic adjustments in payment levels, random delays in payment timing, and changes in the value of the peso, we restrict the sample to the years 2004–2007, when no new PROGAN enrollment decisions were made (table E3, online appendix). Column (4) shows that there may have been effects up to a reduction of 4 per cent in the hectares submitted per eligible zone, although this effect disappears when we add the eligible zones controls (column (5)). If PROGAN reduces enrollment in the PES, we would be understating the interactions on the deforestation side.

Table 3.

Regressions of PES submitted on PROGAN enrollment

Note: Years 2004–2015. Mean of DV in 2004 is 7.3. The panel is unbalanced. Robust standard errors are clustered by municipality. Controls included in columns (3) and (5) are eligible zones-specific. They include road network, the percentage within communal land, the percentage of the municipality that is located in an eligible zone, the baseline characteristics of pasture (both natural pasture and pasture associated with livestock production).

Further tests reveal no evidence of reverse causality. We examine this in a regression of PROGAN enrollment on PES area enrolled (table E4, online appendix) and on PES area submitted (table E5, online appendix) for the years 2004, 2008 and 2014 using the PES eligible zones as an instrument for PES enrollment. These results suggest that PROGAN did not affect the willingness to enroll in PES and, similarly, that PES did not affect the willingness to enroll in PROGAN. This means that if the estimations in the next section show interactions between the two programs, they are unlikely to occur due to reduced enrollment in the PES program or due to simultaneity in the enrollment choice.

4.3. Deforestation effects: interactions of PROGAN and PES

Our main estimation for understanding interactions between PROGAN and PES measures deforestation at an aggregated level. This both reduces the noise that arises from imperfect satellite measures of deforestation and implicitly accounts for spillover effects that might occur within a municipality. However, its weakness is that the measure of the PES treatment is very small in magnitude at a municipal level – ranging only from zero to 1.18 per cent of the municipal area. In online appendix F, we examine the subset of land that ever applied for the PES program. This reveals the impact of the PES program on land that was submitted for enrollment, which gives insight into the probable location of the deforestation effects induced by PROGAN.

As in equation (1), we examine regressions with state or municipal fixed effects combined with year effects and standard errors clustered at the municipality level. The dependent variable is the per cent deforestation over baseline forest cover, and we are interested in the interaction between the PES program, measured as the per cent of the municipal area enrolled in the program, and the PROGAN subsidy. In some estimations we restrict the sample to municipalities that ever had PES enrollment, and in others we apply the baseline municipal forest area as weight.

Table 4 shows the results of interactions between the two programs. Although the effect of the PES alone is not our main focus, we include two estimations that show just the PES effect (columns (1) and (2)), and two columns without interactions between the programs. This table and tables with just state effects are available in the online appendix. All columns are unweighted with the exception of column (7). The even columns restrict the sample to only those municipalities where there was ever PES enrollment.

Table 4.

Regressions of deforestation on PES and PROGAN

Note: Years 2001–2014. Unweighted pre-mean of dependent variable is 0.29 %, weighted pre-mean of dependent variable is 0.34 %. Robust standard errors are clustered by municipality. Columns (2), (4), and (6) include only municipalities that ever had PES enrollment and the seventh column includes weights for baseline forest cover.

Higher levels of PES are associated with lower deforestation in both the main and restricted samples. Including the PROGAN subsidy does not substantially change the independent PES impact. However, adding the interaction term between the two programs does: these terms are all negative and statistically different from zero. The effect of PES where there is zero PROGAN enrollment is not statistically different from zero, although the impact of PROGAN where there is no PES is positive and statistically different from zero in most specifications.

A one standard deviation increase in PROGAN increases deforestation by 1.838*0.154 $=0.283$ percentage points (column (3), table 1). The effect of a one standard deviation increase of PES alone (column (1), table 4), is $-0.171*0.367 =-0.063$. The sum of these is an increase in deforestation of 0.22 percentage points. The interaction term (column (5)) shows that deforestation resulting from PROGAN is lower in municipalities where there is higher PES. However, this effect was not sufficiently large on average to eliminate the increase in deforestation from the livestock subsidy. For a municipality without PES, the average livestock subsidy increased the deforestation rate by 11 per cent.Footnote ¹¹ In municipalities with average PES coverage, the effect of the average livestock subsidy was 3 percentage points lower (extracted from column (7), weighted average PES = 0.022). To visualize these results, we present the interaction effects of PROGAN and PES on deforestation in figure 3. A one standard deviation increase in PES would result in a reduction of deforestation nearly compensating the deleterious effects of PROGAN.

Figure 3.

Marginal interaction effects of PROGAN and PES on deforestation. Marginal effects are calculated according to the specification presented in column (5) of table 4. The PROGAN subsidy/ha label represents the full range of the program. Marginal effects on deforestation are depicted for: no PES enrollment, PES/ha enrollment at the average, and given a one standard deviation increase from the average enrolled PES/ha.

The results are robust to restricting the analysis to the first PROGAN wave. In this case, the deforestation effect of the subsidy and the deterrent effect of PES were about 50 per cent bigger in the first round than for our whole study period (online appendix table E6).

Online appendix F details our analysis of all the land that was submitted to the PES program over this period at the parcel level. Using rejected land as a counterfactual for land that was enrolled, we estimate the interaction between the municipality aggregate measures of PROGAN and enrollment in PES at the parcel level. The estimates show that PROGAN increases the probability of deforestation on land that was submitted but not enrolled in the program. The evidence demonstrates that on enrolled land, PES payments served to offset this increase in the probability of deforestation, but were not sufficient to produce additionality beyond that. The combination of results implies that deforestation from PROGAN is occurring both on unenrolled PES land and also on forest that was never submitted to the program.