Next Article in Journal
Integrated Landsat Image Analysis and Hydrologic Modeling to Detect Impacts of 25-Year Land-Cover Change on Surface Runoff in a Philippine Watershed
Previous Article in Journal
Spatial and Temporal Homogeneity of Solar Surface Irradiance across Satellite Generations
 
 
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

Roads as Drivers of Change: Trajectories across the Tri‑National Frontier in MAP, the Southwestern Amazon

1
Department of Geography and Land Use and Environmental Change Institute, University of Florida, Gainesville, FL 32611, USA
2
The Natural Capital Project, NOAA Northwest Fisheries Science Center, Seattle, WA 98112, USA
3
Department of Sociology and Criminology & Law, University of Florida, Gainesville, FL 32611, USA
4
Percy Fitzpatrick Institute, DST/NRF Centre of Excellence, University of Cape Town, Cape Town 7701, South Africa
5
Center for International Forestry Research, Rio de Janeiro, Brazil
6
Geomatics, School of Forest Resources and Conservation, University of Florida, Gainesville, FL 32611, USA
*
Author to whom correspondence should be addressed.
Remote Sens. 2011, 3(5), 1047-1066; https://0-doi-org.brum.beds.ac.uk/10.3390/rs3051047
Submission received: 14 April 2011 / Revised: 12 May 2011 / Accepted: 13 May 2011 / Published: 24 May 2011

Abstract

:
Regional studies of land cover change are often limited by available data and in terms of comparability across regions, by the transferability of methods. This research addresses the role of roads and infrastructure improvements across a tri-national frontier region with similar climatic and biophysical conditions but very different trajectories of forest clearing. The standardization of methodologies and the extensive spatial and temporal framework of the analysis are exciting as they allow us to monitor a dynamic region with global significance as it enters an era of increased road connectivity and massive potential forest loss. Our study region is the “MAP” frontier, which covers Madre de Dios in Peru, Acre in Brazil, and Pando in Bolivia. This tri-national frontier is being integrated into the global economy via the paving of the Inter-Oceanic Highway which links the region to ports in the Atlantic and Pacific, constituting a major infrastructure change within just the last decade. Notably, there are differences in the extent of road paving among the three sides of the tri-national frontier, with paving complete in Acre, underway in Madre de Dios, and incipient in Pando. Through a multi-temporal analysis of land cover in the MAP region from 1986 to 2005, we found that rates of deforestation differ across the MAP frontier, with higher rates in Acre, followed by Madre de Dios and the lowest rates in Pando, although the dominant land cover across the region is still stable forest cover (89% overall). For all dates in the study period, deforestation rates drop with distance from major roads although the distance before this drop off appears to relate to development, with Acre influencing forests up to around 45 km out, Madre de Dios to about 18 km out and less of a discernable effect or distance value in Pando. As development occurs, the converted forest areas saturate close to roads, resulting in increasing rates of deforestation at further distances and patch consolidation of clearings over time. We can use this trend as a basis for future change predictions, with Acre providing a guide to likely future development for Madre de Dios, and in time potentially for Pando. Given the correspondence of road paving to deforestation, our findings imply that as road paving increases connectivity, flows of people and goods will accelerate across this landscape, increasing the likelihood of dramatic future changes on all sides of the tri‑national frontier.

Graphical Abstract

1. Introduction

Land cover change is considered to be one of the more important impacts of the human population on the earth’s systems [1,2]. In particular, the loss of closed-canopy forest at global and regional scales, and in localized “hotspots” around the world, is of high concern for climate systems, local economies and societies, ecosystem sustainability, and human wellbeing [3]. One of the regions of highest concern globally is the Amazon Basin, which contains the largest remaining tracts of intact forest in the world [4]. Deforestation rates in many parts of the Amazon are high, and urgent action is needed to prevent its long-term degradation. Studies of land cover change, and especially of deforestation, often try to discern the dominant drivers of change [1,2]. In many regions of the world, deforestation and development go together, with the processes of industrialization and globalization leading to increased demand for agricultural land, increased crop and livestock production for export markets, and net decreases in forest cover [5]. Such forest transitions have been well documented across the globe. In many developed nations (e.g., UK and France), forest cover dipped below 10% before recovery and reforestation were initiated [6,7]. In developing regions, one of the main goals for sustainability is to minimize the amount of forest (and associated biodiversity) that is lost before the economy matures. In such globally biodiverse hotspots as the Amazon, a decrease in forest area of even 50% would have catastrophic consequences for biodiversity and local communities, as well as for carbon storage, climate change, and numerous other global and regional processes [8].
Policy proposals such as the Reduced Emissions from Deforestation and Degradation (REDD) offer some of the most promising approaches to decreasing forest loss [9,10], but require baseline measures of land cover and land cover change. Implementing REDD necessitates knowing what the forested area is now and what it was in the recent past, and monitoring future changes using a consistent approach. The accurate quantification of forest cover change and the development of a solid understanding of its causes are of paramount importance in developing and implementing forest protection policies.
Drivers of land cover change have traditionally been linked to population growth, agricultural extensification, and infrastructural development [1]. Infrastructural expansion in particular is often seen as a first step in opening up an area for larger colonization and development programs [11,12,13,14]. New or newly paved roads and other infrastructure upgrades bring numerous rapid and complex changes to forested regions. Roads may fragment habitats, degrade stream networks and water quality, foster the spread of exotic invasive species, cause wildlife mortality and species loss, and bring about local climate change [15,16,17]. Roads can also create social conflicts over land and other natural resources, particularly when threatened resources are fundamental to livelihoods [18,19]. More positively, roads provide access to natural resources, facilitate market access for rural producers, allow integration among economic sectors, and reduce the costs of spatial mobility for people, capital and information [20,21,22].
The many dimensions of road impacts on social-ecological systems has led to an emergent focus on “road ecology”, which integrates contributions from transportation planning, hydrology, ecology and other sciences [23,24]. The actual emergence and development of road networks can be studied in tandem with associated land clearing, agricultural field development, and other land use changes which can be linked directly to road development. Changes in land cover occur not only during primary road construction, but also as a result of road upgrades such as paving and the construction of bridges. When studying land cover change over time, the use of satellite imagery is key. Imagery allows us to evaluate land cover change before, during and after road construction. In addition, if studies are undertaken on a large spatial scale, it becomes possible to compare land cover changes in distinct spaces (e.g., different countries or administrative units) with different infrastructure and policies [25].
This research addresses the tri-national frontier region of Bolivia, Brazil, and Peru. The area comprising eight Landsat scenes per date, across five time periods, giving a total of 40 images analyzed. By exploring trends in the same biophysical environment but in three different countries, each with different policies and levels of infrastructure, we were able to test and compare the generality of different hypotheses about road impacts. Specifically, we (a) evaluated infrastructure impacts on land cover by comparing deforestation on each side of the tri-national frontier from 1986 to 2005 at five time-steps; (b) evaluated the dominant land cover trajectories and time periods of intense change on each side of the tri-national frontier; and (c) examined the relationship among land cover change trajectories, especially deforestation, and the development of the road network across the region.
The dominant research hypothesis linked to these research questions is that road access and connectivity, together with location along a gradient of travel time, cost, and proximity to cities, determine the extent of deforestation via the provision of links between markets and source pools of cultivators, loggers, and other actors who remove forest cover. Paved roads offer greater access and hence should facilitate forest conversion to pasture and agriculture. We tested the broad-scale validity of this hypothesis by contrasting levels of infrastructure and land cover trajectories across the three different countries in our study. We also predicted that consolidated frontier clearing should dominate in Acre, due to the time since paving of the Inter-Oceanic Highway in Brazil. Finally, we used our data to explore the implications of continuing and future road development within the region, using comparisons between countries as proxies for the different time periods or stages of infrastructural development.

2. Study Area

Our study area is the “MAP” region of the southwestern Amazon, a tri-national frontier named after the three states that constitute the area: Madre de Dios in Peru, Acre in Brazil, and Pando in Bolivia (see Figure 1). This tri-national frontier was historically covered by humid tropical forest, and remains roughly 90% forested. It is home to the world’s highest levels of terrestrial biodiversity and is considered a global biodiversity “hotspot” [26,27]. However, MAP is a relatively remote area in all three countries, and is characterized by a combination of rich natural resources and low incomes. Such circumstances in the MAP frontier and elsewhere in South America prompted presidents of several countries to constitute the Initiative for Integration of Regional Infrastructure in South America (IIRSA). IIRSA prioritizes cross-border infrastructure projects such as road paving as a means of economic integration and economic development [28,29].
Figure 1. Study area showing the Tri-National region and major roads used for the analysis.
Figure 1. Study area showing the Tri-National region and major roads used for the analysis.
Remotesensing 03 01047 g001
The MAP frontier is among the first wave of IIRSA projects, and is currently being integrated via paving of the Inter-Oceanic highway [28,29]. Once the paving is completed in Peru (currently predicted to occur in 2011), MAP frontier will be linked to Atlantic ports of Southern Brazil as well as Pacific ports in Peru. Paving of the Inter-Oceanic Highway thus constitutes a potentially very significant change to this region [25]. Road paving under IIRSA is likely to bring rapid changes in land use and livelihoods, with the potential prospect of substantial forest and biodiversity loss, changes in land tenure (such as from extractive forest reserves to private agricultural holdings), and unsustainable livelihoods [30]. This is a crucial historical moment at which to obtain estimates of past and present land cover change in order to see how the MAP social-ecological system responds to external shocks brought by migration, investment and new technologies in the wake of infrastructure upgrades [31,32,33]. Given the tri-national differences within the region (the Brazilian side being more developed than the others, followed by Peru and lastly Bolivia) there is considerable spatial variability in land cover changes. This in turn presents opportunities to compare land cover change in areas within MAP that have road paving to those that still lack paving, as a means of evaluating potential land cover change in the future should road paving expand, as governments sharing the tri-national frontier are planning.
Figure 2. Before and after road development for the different regions in (a) Acre in 2002; before and after paving of the Inter-Oceanic Highway; (b) Madre de Dios in 2006–2007 with paving of the Inter-Oceanic underway; and (c) the main road in Pando in 2008, not yet paved, both photographs show the unpaved roads within this region.
Figure 2. Before and after road development for the different regions in (a) Acre in 2002; before and after paving of the Inter-Oceanic Highway; (b) Madre de Dios in 2006–2007 with paving of the Inter-Oceanic underway; and (c) the main road in Pando in 2008, not yet paved, both photographs show the unpaved roads within this region.
Remotesensing 03 01047 g002
Notable among the differences among the sides of the tri-national frontier are the differing levels of infrastructure. Given the importance of accessibility for land cover change, differences in road paving across MAP permit a tri-national comparison to evaluate the impact of new infrastructure on land cover change. The Inter-Oceanic Highway is the major road across the Brazil and Peru regions and, in addition, its paving is a long-awaited and heavily anticipated project between Brazil and Peru. In Acre, Brazil the paving was completed by 2002 and has been underway in Madre de Dios, Peru since 2006, whereas in Pando, Bolivia, paving is very limited, though the Bolivian government has announced plans to pave roads in Pando (Figure 2). Given these differences in the presence of the main road and then the extent of paving, we should expect greater land cover change in Acre than Madre de Dios and little change in Pando. Pando is almost a ‘null model’ or control, with no paving completed or even underway. In addition to the presence of this main paved road, the presence of secondary dirt roads also differs across the national borders, although this analysis will only consider the main roads (Figure 1). In the MAP frontier, Acre has the most extensive network of secondary roads, followed by Madre de Dios and then Pando. It is also likely that differences in secondary roads play a role in deforestation, but due to their size, seasonal impassability, and predominantly dense canopy cover (which make them difficult to detect consistently), secondary roads are not included in this analysis. Here we evaluate only the role of the main roads across the regions, and the impact of paving of these roads (as shown in Figure 1), on deforestation. While only Acre was paved during our time period of study, the positive propaganda in Madre de Dios has been a huge deal, leading to significant migration from the Andean highlands to the lowlands of Madre de Dios which we expect to have some significant impact on the potential land cover change, even in advance of the road paving.

2. Methods

2.1. Image Processing

We created a Landsat TM and ETM+ database comprised of 40 images (Paths 1–3, Rows 67–69 excluding 1/69) for the MAP region over 20 years. Image dates used in this analysis include 1986, 1991, 1996, 2000 and 2005. July represents the best cloud- and smoke-free month of image acquisition. Image preprocessing including: atmospheric and radiometric calibration; standardization of map projection, coordinate system, and datum; and geometric correction to the Global Land Cover Facility Geocover product for 1999/2000. The image preprocessing follows the CIPEC protocol [34] and was standardized for each image, providing a robust preprocessing methodology comparable across dates and country boundaries.
Image mosaics were created for 1986, 1991, 1996, 2000, and 2005 with eight images for each year. Derived data products of tasseled cap brightness, greenness, and wetness indices were calculated along with a mid-infrared vegetation index and a three-by-three moving window variance for each mosaic date as input to a decision tree classification. Due to striping in the visible and thermal bands in many of the available Landsat images, only the near- and mid-infrared bands were used along with the derived products to create a forest, pasture and bare-built classification, regrouped here to a forest and non-forest classification for each mosaic date (see [35] for more detail on processing of imagery). The image striping problem limited the spectral data available, and due to this problem, we created derived products, rather than use much of the raw image bands, as these derived products did not have the striping problem (e.g., TCA analysis which is a form of Principal Components Analysis (PCA) itself a technique commonly used to destripe images, and so the first three components of the TCA were striping free, and used in concert with the unaffected image bands).
The forest non-forest classification was used in this analysis due to the focus on deforestation processes as a function of road building. Differences in timing and type of agriculture made a set agricultural class inaccurate given the available imagery. As such pasture, bare fields and built cover types were grouped into the non-forest class. The forest class included all dense vegetated covers, which would by default include secondary succession as a cover type once a dense canopy was achieved (considered to be 3–5 years within this region). A decision-tree classifier was used for the analysis to allow the incorporation of a series of rules and derived image products within the classification. Compumine software was used, which is a data mining software which predicts the specified land cover classes, and was established here using a split-sample validation, where we used 85% of our training sample points to create the decision rules and tree classifier and the remaining 15% were used to test the tree output. The rules, once developed and tested for accuracy (each year was analyzed separately and percentage accuracy of the rules were 98–99.8% accurate, see [35] for more detailed information) were then incorporated into the ERDAS Knowledge Engineer rule-based classifier to create each year’s land cover classifications. Classification accuracy was assessed using over 350 training samples collected during fieldwork from 2005 to 2006 and Kappa coefficient and overall percent accuracy for each class and for the overall classification, with resulting accuracies for 2005 of greater than 90%. In addition the 2000 image data were also independently checked using ASTER images for the year 2000, and an overall accuracy of 96% was achieved across these products. Given the large number of images, image years and trajectories to be created, the use of a two-class classification was ideal for this purpose and was also determined to be accurate based on field data and alternative image sources. As such a forest/non-forest trajectory image was created from these classifications resulting in 32 possible change classes. Since deforestation is a categorical rather than a continuous change in forest cover, [36] change trajectories were chosen as the best means to analyze temporal changes in forest cover and to calculate the rates of deforestation [37,38]. Image change trajectories are defined as sequences of successive changes in land cover types providing information on changes between two or more time periods of an area or region. That is, the number of change categories is defined as:
m t = m c t
where mt is the number of change trajectories, mc is the number of land cover classes defined and here is either forest or non-forest, and the superscript t is the number images [37], which in this example is 5 separate dates. As such the number of possible change classes is 2 × 2 × 2 × 2 × 2, or 32 possible classes. Due to this number of change classes becoming quite large (Table 1(a) lists all 32 change trajectories), this research also created a set of summary trajectories which were of the most interest and which incorporated the major trends occurring by grouping the trajectories to show the overall trend (Table 1(b)).
Table 1. Land Cover Change Trajectories as a percent of the total landscape for (a) all classes, (b) summary of the percent of the landscape in each major transition group.
(a)
(a)
ClassMAPAcre, BrazilMadre de Dios, PeruPando, Bolivia
Stable Forest (F-F-F-F-F)89.32181.71893.87997.283
Stable Non-forest (NF-NF-NF-NF-NF)0.8541.2930.0560.131
Tending towards Deforestation4.75710.4231.5201.373
Nonforest since 1991 (F-NF-NF-NF-NF)0.6421.6850.0750.119
Nonforest since 1996 (F-F-NF-NF-NF)0.7871.9110.1140.129
Nonforest since 2000 (F-F-F-NF-NF)0.9722.1570.1880.368
Nonforest since 2005 (F-F-F-F-NF)2.3554.6701.1440.757
Tending towards Reforestation0.9350.2831.6590.093
Forested since 1991 (NF-F-F-F-F)0.6520.1081.3070.060
Forested since 1996 (NF-NF-F-F-F)0.2130.0650.3140.020
Forested since 2000 (NF-NF-NF-F-F)0.0250.0490.0130.006
Forested since 2005 (NF-NF-NF-NF-F)0.0460.0610.0250.007
Rotational4.1336.2842.8851.119
F-NF-F-NF-F0.0950.1370.0900.033
NF-F-NF-F-NF0.0890.0470.0150.005
F-F-F-NF-F0.6971.0100.8350.321
F-F-NF-F-F0.4620.5050.2710.212
F-F-NF-F-NF0.3200.6650.0770.062
F-F-NF-NF-F0.1200.2190.0870.024
F-NF-F-F-F0.8121.3720.8800.116
F-NF-F-F-NF0.1540.3290.0810.044
F-NF-F-NF-NF0.2260.4980.0480.090
F-NF-NF-F-F0.0490.1210.0190.011
F-NF-NF-F-NF0.1360.3480.0180.027
F-NF-NF-NF-F0.0560.1410.0250.010
NF-F-F-F-NF0.0800.0680.0630.012
NF-F-F-NF-F0.0830.0170.1250.007
NF-F-F-NF-NF0.0750.0870.0280.017
NF-F-NF-F-F0.0400.0230.0230.003
NF-F-NF-NF-F0.0320.0200.0290.002
NF-F-NF-NF-NF0.2430.1740.0360.016
NF-NF-F-F-NF0.0700.0920.0440.014
NF-NF-F-NF-F0.0480.0210.0550.008
NF-NF-F-NF-NF0.1200.1840.0200.060
NF-NF-NF-F-NF0.1270.2050.0160.025
(b)
(b)
ClassMAPAcre, BrazilMadre de Dios, PeruPando, Bolivia
Stable Forest89.3281.7293.8897.28
Stable Non-forest0.851.290.060.13
Towards Deforestation4.7610.421.521.37
Towards Reforestation0.940.281.660.89
Rotational4.136.282.891.12

2.2. GIS Analysis

Spatial analysis of road effects on forest/non-forest trajectory change was conducted using a GIS-based model. Instead of using a vector-based buffer analysis to create fixed interval multiple-ring buffer zones, a raster layer of distance to road network was generated and reclassified to distance zones based on a dynamic distance parameter. The classified distance zone was then used in a GIS zonal statistics analysis where the forest/non-forest trajectory image with 32 possible change classes is the value layer. After parameter calibration and sensitivity analysis, distance zones from 1 km to 75 km in 1 km increments were chosen. With the function of Tabulate Area in ArcGIS, a matrix of cross-tabulated area between the distance and the change trajectory was created. This technique allows for a more continuous interpretation of the impact of distance from roads and for the evaluation of differences across countries by not imposing one set of distance buffers on all landscapes.

3. Results

3.1. Land Cover Change Trajectories

Across the entire landscape, the overwhelming land cover trajectory is that of stable forest, representing approximately 89% of the study region (Table 1). Of the other 11%, 5% relates to areas which have been deforested and remained clear, with the rate of clearing increasing over time from 0.6% by 1991, 0.8% by 1996, 1% by 2000 and increasing to 2.3% by 2005. Beyond clearing, 1% of the landscape is in land which was cleared before 1986 and remained cleared since. The remaining 4% is represented by rotational agricultural covers which rotate between clearings and secondary successional forest regrowth with no changes in pattern over time. Finally, 1% of the landscape has undergone reforestation and remained in this final forest cover class. This class also shows an inverse pattern to that of deforestation over time, with decreasing reforestation from 0.7% in 1991, to 0.2% in 1990, 0.03% by 2000 and 0.05% by 2005.
Despite this overall regional trend there are some startling differences when we look separately at each country (Table 1(b), Figure 3). Acre, Brazil has the lowest overall rates of stable forest, with approximately 82% area and about 1.3% in permanent clearings. Over 10% of the landscape has been deforested with this increment increasing over time from 1.7% in 1991, 1.9% in 1990, 2.2% in 2000 and finally jumping to 4.7% of the landscape undergoing deforestation by 2005. Just over 6% of the landscape is within the rotational agriculture and forest regrowth class and less than 0.3% is tending towards reforestation. Figure 3 clearly illustrates a traditional fishbone pattern of forest clearing along roads with expansion outward from roads as time has progressed. Thus, initial clearings along roads were followed later by clearing of plots farther out as available land along road frontages was already in agricultural plots.
Figure 3. Land Cover Trajectory for Acre from 1986–1991–1996–2000–2005. White areas represent areas of cloud or no data on any one date which were then removed from the analysis.
Figure 3. Land Cover Trajectory for Acre from 1986–1991–1996–2000–2005. White areas represent areas of cloud or no data on any one date which were then removed from the analysis.
Remotesensing 03 01047 g003
In Madre De Dios, Peru (Table 1(b)), about 94% of the landscape is under stable forest cover and less than 0.06% is in permanent clearings. Areas tending towards deforestation were 0.07% in 1991, 0.1% in 1996, 0.2% in 2000 and then increases to 1.1% by 2005. Approximately 1.7% of the landscape was tending towards reforestation but most of this occurred in 1991, with 1.3%, then 0.3% in 1996, down to 0.01% in 2000 and 0.03% in 2005. Reforestation patterns for Madre de Dios are interesting due to their early peak, which resulted from the failed 1980s settlement projects and the closing of the Agrarian Bank, which in turn resulted in land abandonment and reforestation [39]. This was a temporary feature on this landscape, however, as forest clearing and agricultural development were reinitiated in the late 1990s and 2000s. Almost 3% of the landscape is in rotational agriculture (Table 1(a)). Viewed spatially (Figure 4), much less of Madre de Dios has been cleared than Acre. While a single linear feature—the Inter-Oceanic Highway—and clumped clearings radiating out from towns are evident, the more developed fishbone pattern is lacking. We note that the bare soils seen in the lower left of Madre de Dios are the Andean highlands, and not Amazon forest clearings.
Figure 4. Land Cover Trajectory for Madre de Dios from 1986–1991–1996–2000–2005. White areas represent areas of cloud or no data on any one date which were then removed from the analysis.
Figure 4. Land Cover Trajectory for Madre de Dios from 1986–1991–1996–2000–2005. White areas represent areas of cloud or no data on any one date which were then removed from the analysis.
Remotesensing 03 01047 g004
Finally, Pando, Bolivia shows the area with the least change as over 97% of the landscape is found in stable forest cover and less than 0.15% is in permanent clearings (Table 1(b)). Approximately 1.4% of the landscape has been deforested, with over half of this (0.76%) occurring in 2005, 0.4% by 2000, 0.13% by 1996 and 0.12% by 1991. About 1% of the landscape is in the rotational agriculture class (Table 1(a)). Spatially (Figure 5), Pando shows very little in terms of deforestation and what has occurred appears to be spillover from the Brazilian border area in the northern portion of Pando around its capital Cobija. Pando does exhibit deforestation along two roads extending from Cobija across Pando, and in selected areas along major rivers where there are agro-extractive communities.
Figure 5. Land Cover Trajectory for Pando from 1986–1991–1996–2000–2005. White areas represent areas of cloud or no data on any one date which were then removed from the analysis.
Figure 5. Land Cover Trajectory for Pando from 1986–1991–1996–2000–2005. White areas represent areas of cloud or no data on any one date which were then removed from the analysis.
Remotesensing 03 01047 g005
Overall then, from Table 1, extent of deforestation can be linked to road paving as deforestation was highest in Acre, where paving was complete, followed by Madre de Dios, where paving was underway, followed by Pando, which lack paving. Further, from Figure 3, Figure 4 and Figure 5, much deforestation exhibits linear patterns in all three sides of the MAP frontier, and these features appear to dominate when looking at the locations of forest clearing and the acceleration of clearings over the more recent dates.
Given these findings, we can also assess the expansion of forest clearing as a function of increasing distance from the Inter-Oceanic Highway and other primary roads in the MAP frontier (Figure 1). We therefore calculated deforestation percentages by distance from primary roads (Figure 1) for each side of the tri-national frontier (Figure 6). A key finding is that all distance-deforestation curves show similar patterns with most deforestation occurring closer to the main roads. In Pando, most deforestation occurs in areas close to the Inter-Oceanic Highway and other primary road. Thus, all three sides of the MAP frontier are clearly impacted by road development, and the role of roads as a dominant driver of deforestation is hard to dispute.
Figure 6. Land Cover Trajectory of Deforestation across time periods for (a) Acre, (b) Madre de Dios and (c) Pando. [Note the y-axes scales differ for each graph in order to most clearly show the trends across each region].
Figure 6. Land Cover Trajectory of Deforestation across time periods for (a) Acre, (b) Madre de Dios and (c) Pando. [Note the y-axes scales differ for each graph in order to most clearly show the trends across each region].
Remotesensing 03 01047 g006
While the total amount of forest cleared is highest in Acre, followed by Madre de Dios and then lastly Pando with less than 1% of its forest cover being lost from 2000 to 2005 (which is the highest rate throughout the time period studied) all three follow similar patterns. The most rapid rate of clearing occurs within the first 10 km back from the road, although this is simply the highest rate and beyond this initial distance the patterns and rates vary quite significantly by region. This pattern is especially true for Acre and Madre de Dios (Figure 6(a,b)) where road paving is relatively advanced. This is somewhat less the case for Pando where forests along the dirt roads are beginning to be cleared but the area cleared is quite minor, and distance from road appears to be somewhat less significant (Figure 6(c)). This result is as expected given the seasonal impassability of this road and its lack of development, connectivity or paving and so it is much less likely to exert a significant driving force across this landscape. For Madre de Dios, where development is still underway as main roads were present in 2005 (Figure 1) but were not yet paved (paving began in 2006–2007 but there was much development in advance of this paving and along the dirt main roads) and, as such, the distance to road is still a dominant variable, in part due to forest road frontage still being available for clearing, in comparison to Acre where all frontage roads were already cleared. As such, in Madre de Dios the strong influence of deforestation occurs within 18 km of the roads and beyond this distance the rate and amount of clearings drops off significantly (Figure 6(b)) and this is all along the unpaved main roads, and can only be expected to increase with paving. In comparison, the role of the roads in Acre has a large influence up to around 45 km until the rate and amount of deforestation drop off (Figure 6(a)), and again these roads have been paved since 2002, although patterns of clearing were also apparent here along the unpaved roads pre-2002, in advance of the paving, but along the main roads. Again, Pando has very little clearing overall and also is the least impacted by distance from the road due to the few unpaved roads in country, none of which are main roads studied in this analysis and its distance to the Inter Oceanic Highway, not just in terms of kilometers, but also including a national border. Overall, the presence of the main roads (Figure 1) does lead to clearing forest cover, and this rate of clearing appears to increase as the roads are paved.

4. Discussion

Our results show a strong influence of roads and road paving on deforestation in the MAP region, with support for our starting hypothesis coming both from trends within each country and from comparisons between countries. Previous results from the Brazilian Amazon [12] have suggested that within 10 km of roads there is a 30% forest loss, between 11–25 kms a 20% loss of forest and from 26–50 km a 15% forest loss. The development of new roads and road paving elsewhere in the Amazon thus implies increased forest loss and a spatial pattern of higher loss closer to roads. We found roads to be a driver of forest clearing in this region but at lower rates than those previously reported [12], even for Acre, Brazil. We attribute this result in part to the remote location of MAP, which even with the road developments and road paving is still less accessible than other parts of Brazil [25].
In Madre de Dios, the road is a HUGE deal and has been showered with positive propaganda by the national government and the participating construction firms. It is one of several reasons why migration from the Andean highlands to the lowlands in Madre de Dios has (again) accelerated. The latest Peruvian census shows rapid growth in Madre de Dios. So forest clearing proceeded in part due to the attention and the migration. Another key factor was a change in Peru's agrarian law that unworked land could be expropriated, which also stimulated forest clearing to establish clear tenure, something seen in previous decades in Brazil. Madre de Dios also saw especially rapid deforestation due to national economic growth, the onset of road paving itself, and the rise of gold prices. All of these trends have since continued and we have more recent images that confirm an expansion of deforestation since 2005. We are working to quantify the extent and render new estimates comparable to our existing data.
In Bolivia, deforestation rose due to spillover effects and land speculation. Brazilians with deforestation limits on their ranches in Acre set up ranches across the border in Bolivia. Those areas are visible outside of Cobija and in other places along the northern border of Pando (Figure 5). In addition, the Bolivian government has announced future road paving in Pando, which likely helps explain incipient forest clearing along roadsides, even farther from the Brazilian border. Land speculation driven by such announcements has stimulated deforestation elsewhere in the Amazon in the past.
For a very small portion of our much larger study region, Almeyda Zambrano et al. [25] studied the role of roads as one possible driver of deforestation. However, the roads in this region were paved starting in the 2000s and so the study period 1982–1996–2002 was not really long enough to link to infrastructure changes, with only a two year time frame since paving began (2000–2002) at a maximum. Almeyda Zambrano et al. [25] did determine that road development, especially of secondary roads, combined with available credit likely explained much of the forest loss from 1986 to 1996 but that from 1996 to 2002 no significant increase in deforestation was seen as many prime areas were already cleared by then and the full impact of the road simply wasn’t evident by 2002. Our study covers a larger spatial and temporal scale (specifically five years post 2000) and does show increased rates of forest clearing across time with a much higher rate for 2005—which fits with the expected role of roads for this region. Notably, the most recent period (2000–2005) exhibits the highest rate of forest cover change in all three countries, and coincides with the completion of paving in Acre and preparations for paving in Madre de Dios. It is therefore not surprising that clearing was highest during that period in Acre followed by Madre de Dios and then Pando. Rates of change are still relatively low for Madre de Dios and very low for Pando compared to Acre, but again all three show the impact of roads on their landscapes (Figure 3, Figure 4, Figure 5 and Figure 6).
Rather than offer lists on the multiple causal factors of forest clearing, it is probably more useful to focus on a few factors important on all three sides. We have already discussed road paving. Another issue is the relative importance of cattle. In Acre, the cattle herd is very large and ranching demands large cleared areas. By comparison, the herds in Madre de Dios and Pando are small. Hence the much greater overall area cleared in Acre than elsewhere. A third factor is land tenure. Whereas tenure is largely settled in Acre now, there remain lands with ambiguous tenure security in Madre de Dios and especially in Pando. This encourages new land settlement in those areas, something that accelerated as road paving accelerated, especially after 2000. This helps account for the rapid rise in deforestation, especially in Madre de Dios (in relative terms).
One of the strengths of our study is that the role of roads can be explicitly addressed in a comparative fashion where we have a potential space for time substitution based on the level of development in each of the three countries. While the extent of road paving differs across the MAP frontiers and helps explain variation in deforestation, our findings also suggest similar patterns of change due predominantly to time since road paving. Acre gives us a glance at a potential future state of Madre de Dios, Peru; and Madre de Dios can serve as a future potential state of Pando, Bolivia. Acre has paved roads since 2002 and the presence of a major road for much longer (Figure 1) and as a result has much greater deforestation (amounts and rates). Madre de Dios has relatively middling deforestation and up through 2006 the main roads were unpaved (although paving is now underway here it is not in the time frame of this research). Finally, Pando lacks main roads or paved roads and as such has much less deforestation (amounts and rates). As such, there is a correspondence in the presence of main roads and the process of paving (and development) and deforestation rates and amounts, across these three countries. Consequently, the progression of paving in Madre de Dios and in the future in Pando suggests greater deforestation there in the future, with the main roads producing an increase in the area cleared and the paving accelerating the rate of clearing. Preliminary analysis of more recent satellite imagery for Madre de Dios (Chavez, personal communication 2011) suggests that since 2005, deforestation has accelerated there as road paving has continued.
These concerns aside, the MAP frontier is still early on in the development-deforestation process. Over 89% of the landscape still remains forested, a number which increases to 97% for Pando. The alarming rates of deforestation, as seen elsewhere in the Amazon across the last twenty years [41] are not yet occurring in the MAP frontier. Given that many of the frontier regions are now trying to slow, halt or even reverse former deforestation trends [41] this may bode well for the future of the MAP frontier. Consequently, the MAP frontier is a region worthy of further study for biodiversity and land cover maintenance, in addition to the implications of the stable forest cover since 1986 for REDD type programs [10,42]. Understanding contemporary drivers and patterns of land cover change will allow for better management and planning of future land cover change, a key issue in REDD landscapes [10,42].
One of the novelties of our research is that the MAP frontier is not currently an area of rapid or extensive deforestation, and so monitoring change in this region as it develops and becomes integrated into the global arena is of great interest. Additionally, the tri-national frontier allows us to introduce an interesting dialogue of the national scale and its role in an area otherwise geographically and climatically similar. Mertens et al. [43] found that deforestation studies should expect to obtain very distinct results as a function of scale, subregion, and time period. The extra insights offered by a three-way comparison can motivate future analyses of spatial-temporal similarities and variations in land cover change trajectories across the tri-national frontier.
A major concern in the MAP frontier is that with improved infrastructure and accessibility, a massive increase in deforestation will result [44]. Many would argue that the lack of accessibility is what has kept this region so forested and so with the increased access comes increased risk of deforestation. Future changes across this region as it opens up to more development and trade must therefore be carefully monitored.

5. Conclusions

We explored the hypothesis that road access determines the extent and spatial configuration of deforestation. Evaluation of the different trajectories across the three countries revealed clearly that roads are the dominant, though clearly not the only, driver of deforestation. Main roads and paved roads offer greater accessibility, facilitating greater clearing to pasture and agriculture, as seen clearly in Brazil. The process of road building is underway in Peru and not really initiated yet in Bolivia. The spatially contiguous nature of the analysis allows for control of the biophysical conditions across the study region; the methodologies for land cover analysis are identical due to the large spatial extent and the longer time scale, and the 5-year repeat interval really allows for a time series approach. We can see and evaluate the consolidated frontier clearing which dominates in Acre (Brazil), due to its longer access to the paved BR-317 (Inter-Oceanic highway), the initiation of clearing in Peru which accelerates in the final time step of the analysis along this main road as paving is about to initiate, and for both of these locations the clearing occurring along the roads and then inwards from cleared areas along these roads back into the intact forest cover. Finally, for Bolivia there is no real change in forest cover or pattern of clearing as the roads in this region are not main roads, nor are they paved. Any plans to expand them or pave them are still under discussion at this time. The research presented here corroborated the expectation that roads are a significant driver of deforestation and that the paving of the road network will increase the amount and rate of clearing seen across the entire region. In addition the creation of a spatially and temporally extensive database is really just the beginning of the trajectory analysis—so we can now continue to monitor and understand this important region of the world as the changes to infrastructure and connectivity continue to accelerate.

Acknowledgements

The research presented here was funded as part of an NSF Human and Social Dynamics Program (FY2005) project, entitled “Agents of Change: Infrastructure Change, Human Agency, and Resilience in Social-Ecological Systems” #0527511. We acknowledge Daniel Rojas (Amazonian University of Pando), Veronica Passos (Federal University of Acre), Bertha Ikeda and Omar Burga (National Amazonian University of Madre de Dios) for in-country institutional support, and Americo Quevedo and Gabriel Alarcon (National Amazonian University of Madre de Dios), Floridia Saavedra (Amazonian University of Pando), Andrea Chavez (University of Florida) for contributing to field data collection.

References

  1. Lambin, E.F.; Geist, H. Land-Use and Land-Cover Change: Local Processes and Global Impacts; Springer-Verlag: Berlin, Germany, 2006. [Google Scholar]
  2. Gutman, G.; Janetos, A.C.; Justice, C.O.; Moran, E.F.; Mustard, J.F.; Rindfuss, R.R.; Skole, D.; Turner, B.L., II.; Cochrane, M.A. Land Change Science: Observing, Monitoring and Understanding Trajectories of Change on the Earth’s Surface; Kluwer Academic Publishers: Dordrecht, The Netherlands, 2004. [Google Scholar]
  3. Grau, H.R.; Aide, M. Globalization and land-use transitions in Latin America. Ecol. Soc. 2008, 13. article 16. [Google Scholar]
  4. Keller, M.; Bustamante, M.; Gash, J.; Silva Dias, P. Amazonia and Global Change; American Geophysical Union: Washington, DC, USA, 2009. [Google Scholar]
  5. Rudel, T.K. Tropical Forests: Regional Paths of Destruction and Regeneration in the Late Twentieth Century; Columbia University Press: New York, NY, USA, 2005. [Google Scholar]
  6. Mather, A.S. The forest transition. Area 1992, 24, 367–379. [Google Scholar]
  7. Mather, A.S.; Needle, C.L.; Fairburn, J. Environmental Kuznets curves and forest trends. Geography 1999, 84, 55–65. [Google Scholar]
  8. Malhi, Y.; Roberts, T.; Betts, R. Special Issue “Climate change and the fate of the Amazon”. Phil. Trans. Roy. Soc. B 2008, 363, 1498. [Google Scholar]
  9. Angelsen, A. Realising REDD+: National Strategy and Policy Options; CIFOR: Bogor, Indonesia, 2009. [Google Scholar]
  10. Stickler, C.M.; Nepstad, D.C.; Coe, M.T.; McGrath, D.G.; Rodrigues, H.; Walker, W.S.; Soares-Filho, B.S. The potential ecological costs and co-benefits of REDD: A critical review and case study from the Amazon region. Glob. Change Biol. 2009, 15, 2803–2824. [Google Scholar] [CrossRef]
  11. Chomitz, K.M.; Gray, D.A. Roads, land use, and deforestation: A spatial model applied to Belize. World Bank Econ. Rev. 1996, 10, 487–512. [Google Scholar] [CrossRef]
  12. Laurance, W.F.; Cochrane, M.A.; Bergen, S.; Fearnside, P.M.; Delamonica, P.; Barber, C.; D’Angelo, S.; Fernandes, T. The future of the Brazilian Amazon: Development trends and deforestation. Science 2001, 291, 438–439. [Google Scholar] [CrossRef] [PubMed]
  13. Nelson, G.; de Pinto, A.; Harris, V.; Stone, S. Land use and road improvements: A spatial perspective. Int. Reg. Sci. Rev. 2004, 27, 297–325. [Google Scholar] [CrossRef]
  14. Pfaff, A.; Robalino, J.; Walker, R.; Aldrich, S.; Caldas, M.; Reis, E.; Perz, S.; Bohrer, C.; Arima, E.; Laurance, W.; Kirby, K. Road investments, spatial spillovers, and deforestation in the Brazilian Amazon. J. Reg. Sci. 2007, 47, 109–123. [Google Scholar] [CrossRef]
  15. Coffin, A.S. From roadkill to road ecology: A review of the ecological effects of roads. J. Transp. Geogr. 2007, 15, 396–406. [Google Scholar] [CrossRef]
  16. Forman, R.T.T.; Alexander, L.E. Roads and their major ecological effects. Annu. Rev. Ecol. Syst. 1998, 29, 307–331. [Google Scholar] [CrossRef]
  17. Trombulak, S.C.; Frissell, C.A. Review of ecological effects of roads on terrestrial and aquatic ecosystems. Conserv. Biol. 2000, 14, 18–30. [Google Scholar] [CrossRef]
  18. Leonel, M. Roads, Indians and the Environment in the Amazon: From Central Brazil to the Pacific Ocean; International Working Group for Indigenous Affairs: Copenhagen, Denmark, 1992. [Google Scholar]
  19. Schmink, M.; Wood, C.H. Contested Frontiers in Amazonia; Columbia University Press: New York, NY, USA, 1992. [Google Scholar]
  20. Owen, W. Transportation and World Development; Johns Hopkins University Press: Baltimore, MD, USA, 1987. [Google Scholar]
  21. Straub, S. Infrastructure and Growth in Developing Countries: Recent Advances and Research Challenges; World Bank Policy Research Working Paper No. 4460; Research Support Unit, Development Research Department, World Bank: Washington, DC, USA, 2008. [Google Scholar]
  22. Vance, J.E. Capturing the Horizon: The Historical Geography of Transportation; Harper and Row Publishers: New York, NY, USA, 1986. [Google Scholar]
  23. Forman, R.T.T.; Sperling, D.; Bisonette, J.A.; Clevenger, A.P.; Cutshall, C.D.; Dale, V.H.; Fahrig, L.; France, R.; Goldman, C.R.; Heanue, K.; et al. Road Ecology: Science and Solutions; Island Press: Washington, DC, USA, 2003. [Google Scholar]
  24. Forman, R.T.T. Road ecology’s promise: What’s around the bend? Environment 2004, 46, 8–21. [Google Scholar] [CrossRef]
  25. Almeyda Zambrano, A.M.; Broadbent, E.N.; Schmink, M.; Perz, S.G.; Asner, G.P. Deforestation drivers in southwest Amazonia: Comparing smallholder farmers in Inapari, Peru and Assis Brasil, Brazil. Conserv. Soc. 2010, 8, 157–170. [Google Scholar] [CrossRef]
  26. Myers, N.; Mittermeier, R.A.; Mittermeier, C.G.; da Fonseca, G.A.B.; Kent, J. Biodiversity hotpots for conservation priorities. Nature 2000, 403, 853–858. [Google Scholar] [CrossRef] [PubMed]
  27. Killeen, T.J.; Solórzano, L.A. Conservation strategies to mitigate impacts from climate change in Amazonia. Phil. Trans. Roy. Soc. B 2008, 363, 1881–1888. [Google Scholar] [CrossRef] [PubMed]
  28. CEPEI (Centro Peruano de Estudios Internacionales). La Integración Regional Entre Bolivia, Brasil y Peru; Wagner Tizón, A., Gadea Duarte, R.S., Eds.; CEPEI: Lima, Peru, 2002. [Google Scholar]
  29. Iniciativa para la Integracion de la Infraestructura Regional Suramericana (IIRSA). 2008. Available online: http://www.iadb.org/intal/intalcdi/PE/2010/05287a05.pdf (accessed on 23 May 2011).
  30. Killeen, T.J. A Perfect Storm in the Amazon Wilderness: Development and Conservation in the Context of the Initiative for the Integration of Regional Infrastructure of South America (IIRSA); Conservation International: Arlington, VA, USA, 2007. [Google Scholar]
  31. Brown, I.F.; Brilhante, S.H.C.; Mendoza, E.; Ribeiro de Oliveira, I. Estrada de Rio Branco, Acre, Brasil aos Portos do Pacífico: Como Maximizar os Benefícios e Minimizar os Prejuízos para o Desenvolvimento Sustentable da Amazônia Sul-Ocidental. In La Integración Regional Entre Bolivia, Brasil y Peru; CEPEI: Lima, Peru, 2002. [Google Scholar]
  32. Perz, S.G.; Shenkin, A.; Barnes, G.; Cabrera, L.; Carvalho, L.A.; Castillo, J. Connectivity and Resilience: A multidimensional analysis of infrastructure impacts in the Southwestern Amazon. Soc. Indic. Res. 2011. [Google Scholar] [CrossRef]
  33. Mendoza, E.; Perz, S.; Schmink, M.; Nepstad, N. Participatory stakeholder workshops to mitigate impacts of road paving in the southwestern Amazon. Conserv. Soc. 2007, 5, 1–27. [Google Scholar]
  34. Moran, E.F.; Ostrom, E. Seeing the Forest and the Trees: Human-environment Interactions in Forest Ecosystems; MIT Press: Cambridge, MA, USA, 2005; p. 456. [Google Scholar]
  35. Marsik, M.; Stevens, F.; Southworth, J. Rates and patterns of land cover change and fragmentation in Pando, northern Bolivia, 1986 to 2005. Progr. Phys. Geogr. 2011. [Google Scholar] [CrossRef]
  36. Woodcock, C.E.; Ozdogan, M. Trends in land cover mapping and monitoring. In Land Change Science; Gutman, G., Ed.; Springer: New York, NY, USA, 2004; pp. 367–377. [Google Scholar]
  37. Petit, C.; Scudder, T.; Lambin, E. Quantifying processes of land-cover change by remote sensing: Resettlement and rapid land-cover changes in south-eastern Zambia. Int. J. Remote Sens. 2001, 22, 3435–3456. [Google Scholar] [CrossRef]
  38. Southworth, J.; Munroe, D.; Nagendra, H. Land cover change and landscape fragmentation—Comparing the utility of continuous and discrete analyses for a Western Honduras region. Agric. Ecosyst. Environ. 2004, 101, 185–205. [Google Scholar] [CrossRef]
  39. Chavez, A. Public Policy and Spatial Variation in Land Use and Cover in the Southeastern Peruvian Amazon. Ph.D. Dissertation, University of Florida, Gainesville, FL, USA, 2009. [Google Scholar]
  40. Michalski, F.; Peres, C.A.; Lake, I.R. Deforestation dynamics in a fragmented region of southern Amazonia: evaluation and future scenarios. Environ. Conserv. 2008, 35, 93–103. [Google Scholar] [CrossRef]
  41. Nepstad, D.C.; Soares, B.S.; Merry, F.D.; Lima, A.; Moutnho, P.; Carter, J.; Bowman, M.; Cattaneo, A.; Rodrigues, H.; Schwartzman, S.; et al. The end of deforestation in the Brazilian Amazon. Science 2009, 326, 1201–1203. [Google Scholar] [CrossRef] [PubMed]
  42. Angelsen, A.; Wertz-Kanounnikoff, S. What are the key design issues for REDD and the criteria for assessing options? In Moving Ahead with REDD—Issues, Options and Implications; Angelsen, A., Ed.; CIFOR: Bogor, Indonesia, 2008; pp. 11–21. [Google Scholar]
  43. Mertens, B.; Kaimowitz, D.; Puntodewo, A.; Vanclay, J.; Mendez, P. Modeling deforestation at distinct geographic scales and time periods in Santa Cruz, Bolivia. Int. Reg. Sci. Rev. 2004, 27, 271–296. [Google Scholar] [CrossRef]
  44. Dourojeanni, M.; Barandiaran, A.; Dourojeanni, D. Amazonia Peruana en 2021: Explotacion de Recursos Naturales e Infraestructura; SPDA: Lima, Peru, 2010. [Google Scholar]

Share and Cite

MDPI and ACS Style

Southworth, J.; Marsik, M.; Qiu, Y.; Perz, S.; Cumming, G.; Stevens, F.; Rocha, K.; Duchelle, A.; Barnes, G. Roads as Drivers of Change: Trajectories across the Tri‑National Frontier in MAP, the Southwestern Amazon. Remote Sens. 2011, 3, 1047-1066. https://0-doi-org.brum.beds.ac.uk/10.3390/rs3051047

AMA Style

Southworth J, Marsik M, Qiu Y, Perz S, Cumming G, Stevens F, Rocha K, Duchelle A, Barnes G. Roads as Drivers of Change: Trajectories across the Tri‑National Frontier in MAP, the Southwestern Amazon. Remote Sensing. 2011; 3(5):1047-1066. https://0-doi-org.brum.beds.ac.uk/10.3390/rs3051047

Chicago/Turabian Style

Southworth, Jane, Matt Marsik, Youliang Qiu, Stephen Perz, Graeme Cumming, Forrest Stevens, Karla Rocha, Amy Duchelle, and Grenville Barnes. 2011. "Roads as Drivers of Change: Trajectories across the Tri‑National Frontier in MAP, the Southwestern Amazon" Remote Sensing 3, no. 5: 1047-1066. https://0-doi-org.brum.beds.ac.uk/10.3390/rs3051047

Article Metrics

Back to TopTop