they are exploited with cattle, these represent low productivity 
pasture areas. This occurs due to the elevated soil cover with 
natural regrowth (excessive shading) and the difficulties of 
intensive management practices that imply the necessity of 
mechanization (Numata et al., 2007). Thus, the most common 
LUC trajectory was from forest to degraded forest, and to 
deforestation with typical regrowth and regrowth with pasture. 
Pasture/Rice 
4% 
    
Figure 3. Distribution of the LUC classes in 2011 in deforested 
polygons without soy. 
According to data from the TerraClass project, which classified 
the land use cover in 2008 for the total deforested PRODES 
presented in 2007, 46.7% of the deforestations were with clean 
pasture. The natural regrowth class covered 21% of the 
deforested areas and regrowth with pasture covered 8.7%. 
Taking into account that annual crop occupied only 4.9% of the 
deforested area, there was a significant discrepancy between 
these results and those originating from TerraClass for the 
classes of pasture and regrowth. It is likely that these differences 
are due to the fact that in this work, only the first few years after 
deforestation were evaluated, while TerraClass considered the 
historical deforestation since 1988. Therefore, part of the 
recently deforested areas currently in regrowth process or 
covered with pasture with regrowth could still be converted to 
clear pasture during the coming years. 
Another observation for the polygons without soy is that, in 12 
polygons (24.5%) did not occurred the total clearing of the area 
after the shallow cut pointed by PRODES. In all these cases, it 
was observed that subsequent pattern was clear pasture. This 
result is coherent because the deforestation process is a costly 
one and the investment made by the producer is only justified 
when the goal is to use the area more intensively for either cattle 
raise or agriculture. 
It is also interesting to observe that only 2 polygons were 
directly converted to agriculture in 2011. In the event that the 
conversion actually occurred, the low EVI2 peak observed in 
this crop year is likely to be associated with the cultivation of 
rice, since legumes such as soy tend to have elevated EVI2 
peaks at maximum crop development. 
Areas with soy in crop year 2010/11 
Out of the 50 selected polygons with soy in crop year 2010/11, 
39 (78%) were from Mato Grosso, 11 (22%) from Para and 
none from Rondonia. The soy selected polygons were also 
classified according to the year of deforestation detected by 
PRODES. Thirty-two polygons (64%) were from deforestation 
International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Volume XXXIX-B8, 2012 
XXII ISPRS Congress, 25 August — 01 September 2012, Melbourne, Australia 
detected in 2007; 13 polygons (26%) from 2008; 5 polygons 
(10%) from 2009; and none from 2010 indicating that the 
entrance of soy soon after deforestation is not a common 
practice adopted by the farmers in the region. However, the 5 
polygons from 2009 were directly converted to soy. 
Rivero et al. (2009) and Brown et al. (2005) related that even 
though the areas had been deforested with the objective of soy 
cultivation, this transition generally did not occur immediately 
after deforestation. There is a transition process in which the 
cultivation of rice is a common practice during a period which 
can vary from 1 to 3 crop years after deforestation. Our results 
showed that for more than 70% of the analyzed polygons the 
soy crop was likely to be preceded by rice crop. Two main 
factors contribute to this commonly used transition. The first is 
the lower demands for soil fertility and pH for rice cultivation, 
which is corrected by the addition of chemical fertilizers and 
limestone. The second is related to the difficulties of 
mechanized harvesting of the crops, since it is a recently 
deforested area, where generally many irregularities exist in the 
terrain, caused by the pulling of stumps or the occurrence of 
protruding roots. This hampers the operation of combine 
harvester, especially for soy, since this is conducted with 
platforms close to the ground. On the other hand, for rice 
cultivation, the harvesting platform remains higher above 
ground (20 to 30 cm), avoiding possible damage to the cutting 
bar of the platform due to contact with roots or stumps that can 
damage the combine harvester. During the rice cultivation new 
stump and protruding root suppression operations are conducted 
in a way to permit the entrance of soy in following years. 
Nearly half of the soy polygons showed some indication of 
forest degradation prior to the deforestation process which was 
much lower than the 80% of degradation observed for the 
polygons without soy. This might be motivated by the location 
of the agricultural areas. In other words, the current centers of 
agricultural production are concentrated in the oldest regions of 
colonization of the Amazon region, where timber harvesting by 
means of selective logging could have occurred before the year 
2000. In addition, when the farmer makes a decision to increase 
his cultivated area over forest land, this tends to occur in a more 
direct way. The phase of induced fires, for example, during 
several years before the deforestation could not occur if the 
decision to increase the agricultural area is associated with an 
instantly attractive agricultural commodity market price. It was 
also possible to identify the year in which the total clearing of 
the area was made in almost all cases, except for two polygons. 
In approximately 20% of the cases, there were signs of the 
beginning of the regrowth process after the clearing of the area, 
which in none of the cases exceeded two years. Hence, there is a 
transitional pattern which can occur in some cases when the 
farmer does not finalize the preparation of the soil for 
cultivation, immediately after the total clearing of the area, 
concluding the preparation of the soil throughout the following 
years. 
Thus, in the polygons with soy in crop year 2010/11 it was 
possible to identify and trace two main LUC trajectories: 1) 
forest — forest degradation — total clearing of the area — 
agricultural cultivation (predominantly rice) — soy; 2) forest — 
total clearing of the area — agricultural cultivation 
(predominantly rice) — soy. The average duration of the 
transitional cultivation of an annual crop such as rice was two 
crop years from total clearing to soy cultivation. It should be 
noted that in contrast to the polygons without soy, the 
occurrence of soy basically defines the end of the LUC 
  
  
  
    
   
    
  
   
    
   
   
   
    
  
  
  
     
   
  
  
  
  
  
    
   
     
   
  
  
  
    
    
   
   
    
   
   
    
  
    
    
    
   
   
   
   
     
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