3.1. Setup

Consider an economy with infinite periods, overlapping generations and in which individuals live for two periods. In each period, a population with mass normalized to one is born and has a given wealth distribution G _t (W). Initial wealth is received as a bequest.

In period t, individuals decide what to do with their wealth. That is to say, they may buy a plot of land L at a price p, they may clear land D at the frontier at a cost c, with c < p, or they may decide to enter the labor market and receive a wage, w. In the following period, agents receive their revenues (wages and profits) and sell their land to the new generation that is born, in order to consume. Agents are risk neutral and preferences are given by their consumption and whatever is bequeathed to the next generation.

Assunção, (Reference Assunção2008) has demonstrated that, within this type of framework, expected utility may be a function of profits as well as the value of land sold. It is further assumed that there are no credit or land rental markets.Footnote ⁶ This means that cD < W and pL < W. An important assumption to be made, as argued by Tole (Reference Tole2004), is that accessible land is a function of land inequality.Footnote ⁷

If an individual decides to become a farmer, profit will be revenues received from the sale of agricultural products, q, less the wage paid to employees, w. Therefore, it is assumed that there will be a production function with fixed technology in labor and land. In this case, there are no capital gains after land is sold. If the decision is to clear land, it is assumed that the individual does not need to employ labor and receives a profit, b.Footnote ⁸ As everyone is a price taker in land, there is a possibility of capital gains, p − c.Footnote ⁹ This point is crucial, since it is well known that deforestation follows a speculative motive that is linked with the ‘creation of property rights’ (Sant'Anna and Young, Reference Sant'Anna and Young2010).Footnote ¹⁰

3.2. Occupational choices

Summing up, individuals can invest in a farm, engage in deforestation or become agricultural workers. Given the structure described above, expected final wealth will be:

(1) $$E\lpar W_{t+1} \rpar = \left\{{\matrix{{W_t +w} \cr {\lpar p+b\rpar D} \cr {\lpar p+q-w\rpar L} \cr}} \right\}. $$

The occupational choice results from the comparison of the expected final wealth paths in (1). At this point, it assumed that land distribution is not binding on the size of L. Hence, individuals will choose to become farmers if their final wealth from farming is higher than that from clearing land and being a worker:

(2) $$r_L \gt g_D +r_D \quad and \quad W \gt \displaystyle{{w}\over{r_L }}\equiv W_0\comma \; $$

where r _L is the return on farming: (q − w)/p; g _D is the capital gain from selling deforested area: (p − c)/c; and r _D is the return on activity after the land is cleared: b/c. Thus, in order to become a farmer, it is necessary that the return from this activity be larger than that from clearing land, and initial wealth must be larger than w/r _L .

In order to clear land at the frontier, as compared to becoming a worker, initial wealth must be larger than:

(3) $$W \gt \displaystyle{{w}\over{g_D +r_D}}\equiv W_1. $$

Assuming that there is up to that point a constraint on the size of L, it follows that:

3.3. Introducing land inequality

Now, suppose accessibility to land is completely related to land inequality.Footnote ¹¹ This is represented by assuming that there is a limit on the size of land available to be used, L ^F (i) < L. In addition, when an individual receives her/his initial wealth, if her/his option is to keep farming, a portion of his/her wealth will be allocated to an asset that does not provide any interest payment, m. That is to say, W _t = pL ^F  + m. Thus, occupational choices become:

(4) $$E\lpar W_{t+1} \rpar =\left\{\matrix{ {W_t +w} \cr {\lpar p+b\rpar D} \cr {\lpar p+q-w\rpar L^F+m} \cr} \right\}. $$

Comparing final expected wealth, the occupational choice in favor of clearing as compared to working and to farming land will occur if:

(5) $$W \gt \displaystyle{{w} \over {g_D +r_D }}\equiv W_1 \semicolon \; \quad W \gt \displaystyle{{{r_L}{pL}^F}\over{r_D +g_D}}\equiv W_2. $$

It is clear from (5) that the extent of land inequality, as L ^F  = L ^F (i), is a major determinant of the occupational choice. Again, when comparing payoffs between being a farmer and a worker, the following condition exists:

(6) $$L^F \gt \displaystyle{{w} \over {q-w}}. $$

Substituting (6) into farmer's expected final wealth given by (4) yields:

(7) $$W \gt \left(1+\displaystyle{{1} \over {r_L}}\right)w+m\equiv W_3. $$

Thus W ₃ is the threshold that determines the minimum wealth level in order to be a farmer.

3.3.1. Equilibrium

An equilibrium in the market for cleared land must equalize the aggregate demand and the supply of deforested land. Condition (5) determines that every individual with wealth greater than W ₂ demands W/c units of cleared land. Therefore, the equilibrium condition can be arranged as

(8) $$\vint\limits_{W_2 }^\infty {{Wdg}\lpar W\rpar } =cD $$

Thus, the amount of cleared land within a world with land inequality is given by:

(9) $$D=\displaystyle{{\vint_{W_2 }^\infty {{WdG}\lpar W\rpar } } \over {c}}. $$

The result above leads to the following proposition:

Preposition 1. Deforestation is positively related to land inequality (i), land prices (p), cattle ranching profits (b); and negatively related to cost of deforestation (c), and agricultural prices and yields (q). As for wages, the effect is ambiguous.

Proof: See online appendix B, available at http://dx.doi.org/10.1017/S1355770X1600022X.

From the definition of W ₂, it is expected that land inequality, land prices and profitability at the frontier should exert a positive influence on deforestation. On the other hand, profitability of farming and the cost of deforestation should decrease incentives for clearing land. Regarding wages, there are mixed signals: since they reduce the incentive to farm, they should have a positive influence on deforestation, by reducing W ₂. Nevertheless, wages also represent an opportunity cost and, as this increases W ₁, incentives to clear land are also reduced.Footnote ¹² Thus its influence on deforestation cannot be defined a priori.

The equilibrium in the labor market is defined by the aggregate demand for labor that results from farming decisions and supply of labor:

(10) $$\vint\limits_{W_3 }^{W_2 } {{WdG}\lpar W\rpar = {wG}\lpar W_3 \rpar } $$

The equilibrium wage rate is determined by the endowments of the economy and the wealth distribution.

3.4. Empirical implications

In accordance with the previous section, as inequality reduces access to land, individuals become more prone to clear land at the frontier. Therefore, deforestation will be positively affected by land inequality. The effect of land concentration need not be in the same municipality. Instead, it may be possible that inequality in the access to land works as a push factor leading to migration from one municipality to another in the agricultural frontier. This possibility will be fully explored in the empirical approach.

4.1. Deforestation

The National Institute for Spatial Research produces publicly available data on deforestation by municipality in the Brazilian Legal Amazon, through the Project for Monitoring Deforestation in the Legal Amazon (PRODES). PRODES processes satellite images in order to establish the amount of forested and deforested area in a given municipality. Deforestation is the increment in deforested area in a municipality between August of year t − 1 and July of year t. The analysis is based on this periodicity because July and August are the least cloudy months in the region, thus minimizing measurement error problems.

Deforestation is defined as:

$$D_{it} = \ln\left(\displaystyle{{{Def}_{it}} \over {{Area}_{i}}}\right)$$

where Def _it is the total deforestation that occurred in period t; t is defined as the period 2002–2005 for the first set of regressions and 2006–2011 for the second group; and Area _i is the total area of the municipality. Therefore, D _it is the normalized deforested area, since there is a substantial variability in total area and deforestation in the Legal Amazon.

4.2. Land concentration

The Brazilian Institute of Geography and Statistics (IBGE) publishes a detailed Agricultural Census, on a decennial basis, which permits the computation of a Gini index for land holdings. As the censuses were published in 1996 and 2006, referring to land ownership on 31 December of the previous years, data are only available for these years. Therefore, the analysis rests on the assumption that land inequality affects deforestation with a time lag. Furthermore, land concentration is quite stable. Therefore, it can be assumed that inequality from 1995 affects the pattern of deforestation in the period 2002–2005 and that inequality in land holdings in 2005 affects the deforestation process in the period 2006–2011, especially when one considers a Gini index based on the pattern of migrants, as explained below.

Land concentration may act as a push factor, expelling workers without opportunities to access land in a given municipality.Footnote ¹⁴ Thus, it is expected that land concentration in municipality j affects deforestation in municipality i. In order to account for this spatial pattern, a variable has been used that considers these effects of land inequality in other localities. The measure of migration-weighted land concentration for municipality i is based on the municipalities of origin of its migrants. In order to do so, this is computed from populational censuses, published by IBGE, showing the number of the adult population in municipality i that come from other municipalities. A person is defined as a migrant if (s)he lives in the municipality for less than five years.Footnote ¹⁵

Thus, the measure of land concentration is an unweighted average of the Gini of the municipalities from which the migrants came:

$$Composed\; \; Gini_{it-h} =\mathop \sum\limits_{j=1}^{n} n^{-1}\ast Gini_{jt-h}\comma \;$$

where i is the total number of municipalities that supplied migrants to municipality i, irrespective of the number of migrants, Gini _jt is the land Gini index of municipality j at period t − h. Here, t − h is 1995 for the first group of regressions and 2005 for the second group.

It is also possible to define an alternative way of weighting land inequality by considering the share of migrants that each municipality j contributed to the population of municipality i. In that case, the second measure of composed Gini becomes:

$${{Gini}\_{Migrants}}_{it-h} =\sum_{j=1}^{n} \left(\displaystyle{{{Migrants}_{jit-z}} \over {{Total\; \; Migrants}_{it-z}}}\right)\ast Gini_{jt-h}\comma \;$$

where Migrants _jit-z is the number of migrants that have gone from municipality j to i in the previous five years. Total Migrants _{it - z} is the total in-migrant population of municipality i in the previous five years.

As the formula takes into consideration the number of migrants, this second measure of land inequality may lead to an endogeneity problem: migration patterns may be affected by other factors such as the availability of roads. As roads connecting two cities reduce the cost of transport, this factor is expected to raise migration opportunities. Therefore, in this case it is harder to disentangle the effects of land concentration on deforestation. Thus, this variable will only be used as a robustness check to results with the preferred variable: Composed Gini _{it - h} .

It is worth noting that Arima et al. (Reference Arima, Richards, Walker and Caldas2011) and Richards et al. (Reference Richards, Walker and Arima2014) use a similar approach to estimate the indirect effect of the agricultural sector, especially soybean production, on land use in Amazonia.

4.2.1. Rural credit

The Brazilian Central Bank compiles information about every contract of rural credit. Using this rich database, Assuņão et al. (2012) constructed a data set of rural credit by municipality in the Legal Amazon. Here, the total amount of real rural credit normalized by the municipality area is used:

$${Credit}_{it} = ln\left(\displaystyle{{{rural\; credit}_{it}} \over {{area}_{i}}}\right).$$

Data on rural credit is available from 2003 to 2011. Subsequently, the mean of loans between 2003 and 2005 is taken for the first group of regressions, as well as the mean of rural credit _it between 2006 and 2011 for the second set of estimations.

4.3. Cattle prices

A well-established result in the Brazilian Amazon is related to the importance of the expansion of cattle ranching to explain the pattern of deforestation. As this process is driven by the profitability of the activity, a proxy for cattle prices has been computed in each municipality following Assunção et al. (Reference Assunção, Gandour and Rocha2015). These authors argue that prices cannot be considered in the Legal Amazon because this could lead to endogeneity problems. Thus, they consider prices in the southern state of Paraná as exogenous indicators. The prices are deflated to 2010 Brazilian Reais.

In order to have prices for each municipality, Assuņão et al. (2015) will be followed and a weighted real price calculated according to:

$$CP_{it} =C P\_ P R_{t} \ast \displaystyle{{{cattle}_{head_{it-x}}}\over {{area}_{i}}}.$$

Thus, prices in Paraná are weighted for each municipality in the Legal Amazon according to its intensity in cattle ranching as measured by the ratio of the number of head of cattle and total municipality area, considering a lag to avoid endogeneity issues.Footnote ¹⁶ The period t − x is considered as equal to the average of heads of cattle in 2000–2001 and 2004–2005, according to the respective groups of estimations. Finally, the mean of the natural logarithms of CP _it is taken for (in) the periods 2002–2005 and 2006–2011.

4.4. Settlements

The Brazilian Institute for Applied Economic Research (IPEA) gathers data on different kinds of information important for applied economic research and publicizes it through a website, IPEADATA. Data are available there on rural settlements for agrarian reform, originally informed by the National Institute of Colonization and Agrarian Reform (INCRA). Based on this, a measure of settlements was constructed for land reform for the periods 2002–2005 and 2006–2011. Thus,

$${Settlements}_{it} =\displaystyle{{{Area\; of\; settlements\; to\; land\; reform}_{it}} \over{area_{i}}}.$$

4.5. Geographical controls

The literature on deforestation usually discusses the role of geographical variables in explaining municipality variability (e.g., Arima et al., Reference Arima, Richards, Walker and Caldas2011; Assuņão et al., 2015). In order to control for these factors, the logarithm of mean values to rainfall and temperature during the relevant periods (2002–2005 and 2006–2011) were considered, as well as time-fixed variables such as altitude and the municipality coordinates.Footnote ¹⁷

5.1. Identification strategy

In accordance with the predictions of the theoretical framework presented above, there must be a positive association between the magnitude of land inequality and the deforestation rate. Nevertheless, two problems may arise when simply testing this correspondence using an ordinary least squares (OLS) estimation. First, it is possible to have a problem of reverse causality in the model. As deforestation is a form of land-use change, when increasing the supply of land for cattle ranching or agricultural use, it would be no more than coincidence if the concentration of land holdings were not affected. Secondly, the relation proposed might possibly be driven by omitted variable bias.

In order to deal with these potential biases in the estimator, the measure of land concentration is lagged and based on other municipalities, according to the pattern of migration to the municipalities of interest. Thus, the identification strategy adopted relies on the assumption that the way land concentration has been accounted for is not related to the error term.

Therefore, benchmark specification is defined by:

$$D_{it} =\beta_{1} \ast {Composed\; Gini}_{it-h} + \beta_{2} X_{it} + {State}_{i} +\varepsilon_{it}\comma \;$$

where D _it and Composed Gini _it−h are exactly as defined in the section above. X _it is a vector of control variables containing municipality-level information according to the discussion, and State _i is a dummy for the state to which the municipality belongs. Finally ε _it is the error term.

In spite of the fact that the measure of land inequality can deal with reverse causality problems, there is still room for omitted variable bias. For example, agricultural and land prices may influence both the pattern of land concentration, even considering distinct localities, and the process of deforestation.

Then, in order to overcome this possible bias, an IV approach is proposed. This instrument is the ratio of idle productive land to total municipality area. As the Composed Gini variable, this ratio is composed according to the municipalities of origin of migrants to locality i. The argument for using this variable lies in Assunção's (Reference Assunção2008) findings that unproductive farms are larger than agricultural farms on average. Thus, a positive relation between land concentration and the amount of idle productive land should be found.

Regarding concerns with validity of the instrument, the variable is measured 10 years before the land concentration measure is utilized. Thus, the instrument of Composed Gini in 1995 is Composed idle land in 1985.Footnote ¹⁹ In addition, as argued by Walker and Homma, (Reference Walker and Homma1996), in established frontiers, land scarcity arises in part due to land kept idle by large land owners, leading to a process of land concentration.Footnote ²⁰ The difficulties imposed for small producers leads them to bankruptcy and outmigration to new frontiers (Wood, 1983, cited in Walker and Homma, Reference Walker and Homma1996).

5.3. Robustness checks

5.3.1. Exclusion restriction and additional controls

Although results in table 4 show that the IV is related to inequality, it is not clear that the exclusion restriction holds. That is to say, conditional on the controls included in table 4, the amount of idle productive land (10 years before the period under analysis) in the municipalities from which migrants came should have no effect on deforestation in Amazonian municipalities, other than its effect through land inequality. The major concern with this exclusion restriction is that the IV could be correlated with certain push factors to migration that are contemporaneous to the pattern of land concentration and, therefore, may have a direct effect on deforestation.

Therefore, in order to check for the validity of the instrument, a number of variables have been taken into consideration in the municipalities of origin that could plausibly be correlated with both the IV and deforestation. The variables included are seen as possibly affecting the decision to migrate to the frontier. The share of employment in the primary sector, unemployment rate, educational attainment and demographic density are considered in the main regression. In addition, as described by Sousa (Reference Sousa2013), some externalities are important when it comes to pushing migrants from their original locality: violence, measured as homicide rate, and sanitation coverage represent this kind of externality that might also affect the decision to migrate. These variables are constructed in the same way as the Composed_Gini variable, as described before: they are calculated as unweighted averages of the municipalities of origin of migrants.

Table 5 presents the 2SLS estimation, using the additional controls described above. Overall, comparing results from tables 4 and 5, it can be seen that the results change remarkably little with the inclusion of additional controls. Thus, results from table 5, with additional controls, seem to reinforce the validity of the instrument, especially for the period 2002–2005.

Table 5. Robustness checks: two-stage least squares with additional controls

Notes: Analysis is based on a cross-section of municipalities located in the Legal Amazon states of Acre, Amapá, Amazonas, Mato Grosso, Maranhão, Pará, Rondônia, Roraima and Tocantins, which exhibited variation in forest cover during the sample periods. The dependent variable is the log of the annual deforestation increment as a share of total municipality area. Composed variables consider the municipalities of origin of migrants, as described in the text for the Composed_Gini. Additional controls are cattle prices and rural credit, both measured at the municipalities of analysis. Robust standard errors are clustered at the municipality level. Significance: ***p < 0.01, **p < 0.05, *p < 0.1

5.3.2. Different time spans

The results shown above might be driven by the time spans chosen for deforestation rates. In this section, an alternative period classification was chosen in order to test whether results are robust to these alternative specifications.

As Assunção et al. (Reference Assunção, Gandour and Rocha2015) point out, there were two major shifts in command and control policies for deforestation in the Legal Amazon. First, in 2004, a new plan – the PPCDAm – was launched to combat deforestation. The second turning point was the passing of a presidential decree that selected a list of priority municipalities in which to combat deforestation in 2008.

Given these two shifts, in this section, the sample was split into three different periods: 2002–2004, when deforestation reached its maximum; 2005–2008, marked by a shift in the trend; and 2009–2011, with much smaller levels of deforestation, driven by a second shift in the deforestation trend.

Indeed, as can be seen from table 6, results are valid only in the period 2002–2004. For the periods 2005–2008 and 2009–2011, the estimator for the effects of land inequality is not different from zero.Footnote ²³

Table 6. Robustness checks: different time spans

Notes: Analysis is based on a cross-section of municipalities located in the Legal Amazon states of Acre, Amapá, Amazonas, Mato Grosso, Maranhão, Pará, Rondônia, Roraima and Tocantins, which exhibited variation in forest cover during the sample periods. The dependent variable is the log of the annual deforestation increment as a share of total municipality area. Robust standard errors are clustered at the municipality level. Significance: ***p < 0.01, **p < 0.05.

5.3.3. Panel structure

Another way to deal with unobserved effects is to consider a panel structure based on the two periods considered: using a fixed effects model allows us to identify the effects of land concentration on deforestation independent of time-invariant omitted variables. In addition to fixed effects, table 7 presents results based on a panel with the IV above considered.

Table 7. Robustness checks: panel with two stage least squares

Notes: Analysis is based on a panel of municipalities located in the Legal Amazon states of Acre, Amapá, Amazonas, Mato Grosso, Maranhão, Pará, Rondônia, Roraima and Tocantins, which exhibited variation in forest cover during the sample periods. The dependent variable is the log of the annual deforestation increment as a share of total municipality area. Composed variables consider the municipalities of origin of migrants, as described in the text for the Composed_Gini. Additional controls are cattle prices and rural credit, both measured at the municipalities of analysis. Robust standard errors are clustered at the municipality level. Significance: ***p < 0.01, **p < 0.05, *p < 0.1.

Results still point to a positive relationship between land inequality and deforestation, although not statistically significant when considering a fixed effects with IV model. Although different from other results in this paper, it is perhaps unsurprising. Within the period of analysis, the Amazon experienced a large shift in command and control policies that led to a substantial increase in the cost of deforestation, thus leading to a discontinuity in deforestation figures. Therefore, as land inequality has an inertial structural pattern without any sharp changes, when one uses a panel approach, the relationship under investigation is masked by other important factors that are changing fast, such as conservation policies. In such a context, the policy discontinuity increases the cost of deforestation and is not fully captured by the controls, even when controlling for time fixed effects such as heterogeneity in the timing of the introduction of conservation policies is substantial across municipalities.

Thus, the fixed effects model, although helpful in dealing with time-invariant unobservable variables, has a noisy within-variation since deforestation has decreased in the second period due to the shift in its cost, which is an unobservable variable that is varying in time. Overall, these results may be interpreted by the theoretical model provided in section 3. As government policies have become stricter in relation to deforestation, they can be interpreted as an increase in the cost of deforestation. This increase in the cost, as argued by proposition 1, leads to a reduction in the activity of clearing land. Thus, the effect of land inequality becomes ceteris paribus less important.