The Amazon is a globally important system, providing a host of ecosystem services from climate regulation to food sources. It is also home to a quarter of all global diversity. Large swathes of forest are removed each year, and many models have attempted to predict the spatial patterns of this forest loss. The spatial patterns of deforestation are determined largely by the patterns of roads that open access to frontier areas and expansion of the road network in the Amazon is largely determined by profit seeking logging activities. Here we present predictions for the spatial distribution of standing value of timber across the Amazon. We show that the patterns of timber value reflect large-scale ecological gradients, determining the spatial distribution of functional traits of trees which are, in turn, correlated with timber values. We expect that understanding the spatial patterns of timber value across the Amazon will aid predictions of logging movements and thus predictions of potential future road developments. These predictions in turn will be of great use in estimating the spatial patterns of deforestation in this globally important biome.
References
[1]
Foley JA, Asner GP, Costa MH, Coe MT, Defries R, et al. (2007) Amazonia revealed, forest degradation and the loss of ecosystem goods and services in the Amazon basin, Frontiers in Ecology and Environment, 5: 25–32.
[2]
Betts RA, Malhi Y, Roberts JT (2008) The future of the Amazon: new perspectives from climate, ecosystem and social services, Philosophical Transactions of the Royal Society B, 363: 1729–1735.
[3]
Moran EF (1993) Deforestation and land use in the Brazilian Amazon, Human Ecology, 21: 1–21.
[4]
Melillo JM, Houghton RA, Kicklighter DW, McGuire AD (1996) Tropical deforestation and the global carbon budget, Annual Review Energy and Environment, 2: 293–310.
[5]
Malhi Y, Grace J (2000) Tropical forests and atmospheric carbon dioxide, Trends in Ecology and Evolution, 15: 332–337.
[6]
Dirzo R, Raven PH (2003) Global state of biodiversity and loss, Annual Review of Environment and Resources, 28: 137–167.
[7]
Nepstad D, Soares-Filho BS, Merry F, Lima A, Moutinho P, et al. (2009) The end of deforestation in the Brazilian Amazon, Science, 326, 1350–1351:
[8]
Fearnside PM (1987) Deforestation and international economic development projects in Brazilian Amazonia, Conservation Biology, 1: 214–221.
[9]
Verissimo A, Barreto P, Tarifa R, Uhl C (1995) Extraction of a high-value natural resource in Amazonia: the case of mahogany, Forest Ecology and Management, 72: 39–60.
[10]
Mertens B, Poccard-Chapuis R, Piketty MG, Lacques AE, Venturieri A (2002) Crossing spatial analyses and livestock economics to understand deforestation processes in the Brazilian Amazon: the case of Sao Felix do Xingu in south Para, Agricultural Economics, 27: 269–294.
[11]
Caldas MM, Simmons C, Walker R, Perz S, Aldrich S, et al. (2010) Settlement formation and land cover use change: A case study in the Brazilian Amaon, Journal of Latin Amerian Geography, 9: 125–144.
[12]
Laurance WF, Goosem M, Laurance GW (2009) Impacts of roads and linear clearings on tropical forests, Trends in Ecology and Evolution, 24: 659–669.
[13]
Perz SG, Caldas MM, Arima E, Walker RJ (2007) Unofficial road building in the Amazon: socioeconomic and biophysical explanations, Development and Change, 38: 529–551.
[14]
Kirby KR, Laurance WF, Albernaz AK, Schroth G, Fearnside PM, et al. (2006) The future of deforestation in the Brazilian Amazon, Futures, 38: 432–453.
[15]
Southworth J, Marsik M, Qiu Y, Perz S, Cumming G, et al. (2011) Roads as drivers of change: trajectories across the Tri-national frontier in MAP, the Southwestern Amazon, Remote Sensing, 3: 1047–1066.
[16]
Arima EY, Walker RT, Perz SG, Caldas M (2005) Loggers and forest fragmentation: behavioural models of road building in the Amazon Basin, Annals of the Association of American Geographers, 95: 525–541.
[17]
Nepstad DC, Verissiomo A, Alencar A, Nobre C, Lima E, et al. (1999) Large scale impoverishment of Amazonian forests by logging and fire, Nature, 398, 505–508:
[18]
Laurance WF, Albernaz AKM, Schroth G, Fearnside PM, Bergen S, et al. (2002) Predictors of deforestation in the Brazilian Amazon, Journal of Biogeography, 29, 737–748:
[19]
Evans TP, Manire A, De Castro F, Brondizio E, McCracken S (2001) A dynamic model of household decision making and parcel level landcover change in the eastern Amazon, Ecological Modelling, 143: 95–113.
[20]
Verissimo A, Cochrane MA, Souza C JR, Salomao R (2002) Priority areas for establishing national forests in the Brazilian Amazon, Conservation Ecology, 6: 4–13.
[21]
Asner GP, Keller M, Silvas JNM (2004a) Spatial and temporal dynamics of forest canopy gaps following selective logging in the Eastern Amazon, Global Change Biology, 10: 765–783.
[22]
Fearnside PM (2005) Deforestation in Brazillian Amazonia, history, rates and consequences, Conservation Biology, 19: 680–688.
[23]
Bradshaw CJA, Sodhi NS, Peh KSH, Brook BW (2007) Global evidence that deforestation amplifies flood rish and severity in t he developing world, Global Change Biology, 13: 2379–2395.
[24]
Asner GP, Nepstad D, Cardinot G, Ray D (2004b) Drought stress and carbon uptake in an Amazon forest measured with spaceborne imaging spectroscopy, PNAS, 101: 6039–6044.
[25]
Bonan GB (2008) Foresta and climate change, forcings, feedbacks and the climate benefits of forests, Science, 320: 1444–1449.
[26]
Malhi Y, Roberts TJ, Betts RA, Killeen TJ, Li W, et al. (2008) Climate change, deforestation and te fate of the Amazon, Science, 319, 169–172:
[27]
Montagnini F, Jordan CF (2005) Tropical Forest Ecology, Springer, Berlin.
[28]
Merry F, Soares-Filho B, Nepstad D, Amacher G, Rodrigues H (2009) Balancing conservation and economic sustainability: the future of the Amazon timber industry, Environmental Management, 44, 395–407:
[29]
Uhl C, Barreto P, Verissimo A, Vidal E, Amaral P, et al. (1997) Natural resource management in the Brazilian Amazon, BioScience, 47, 160–168:
[30]
Stone SW (1998) Using a geographic information system for applied policy analysis: the case of logging in the Eastern Amazon, Ecological Economics, 27, 43–61:
[31]
ter Steege H, Pitman NCA, Phillips OL, Chave J, Sabatier D, et al. (2003) A spatial model of tree α-diversity and tree density for the Amazon, Biodiversity and Conservation, 12: 2255–2277.
[32]
Prates-Clark CDC, Saatchi SS, Agosti D (2008) Predicting geographical distribution models of high value timber trees in the Amazon basin using remotely sensed data, Ecological Modelling, 211: 309–323.
[33]
Arima EY, Walker RT, Sales M, Souza C JR, Perz SG (2008) The fragmentation of space in the Amazon basin: emergent road networks, Photogrammetric Engineering & Remote Sensing, 74: 699–709.
Gentry AH (1992) A synopsis of Bignoniaceae ethnobotany and economic botany, Annals of the Missouri Botanical Garden, 79, 53–64:
[36]
Baker TR, Phillips OL, Malhi Y, Almeida S, Arroyo L, et al. (2004) Variation in wood density determines spatial patterns in Amazonian forest biomass, Global Change Biology, 10, 545–562:
[37]
Chave J, Muller-Landau HC, Baker TR, Easdale TA, ter Steege H, et al. (2006) Regional and phylogenetic variation of wood density across 2456 neotropical tree species, Ecological applications, 16, 2356–2367:
[38]
ITTO international Tropical Timber Organisation website. 15: Available: http://www.itto.int/Accessed: 2011 Mar.
[39]
Gerwing JJ, Johns JS, Vidal E (1996) Reducing waste during logging and log processing: forest conversion in eastern Amazonia, Unasylva, 187: article 3. 18: Available online at: http://www.fao.org/docrep/w2149e/w2149e0?0.htm Accessed: 2012 Mar.
[40]
R Development Core Team (2009) R, A language and environment for statistical computing. R Foundation for Statistical Computing, Vienna.
[41]
Giraudoux PR (2011) pgirmess: Data analysis in ecology. R package version 1.5.1. 2: http://CRAN.R-project.org/package=pgirme?ss Accessed: 2012 Apr.
[42]
Nepstad D, Merry F, Rodrigues HO, Schwartzman S (2007) The costs and benefits of reducing carbon emissions from deforestation and forest degradation in the Brazilian Amazon, REDD, United Nations Framework Convention on Climate Change (UNFCCC), Conference of the Parties (COP), Thirteenth Session. 2: Available online at: http://www.whrc.org/policy/pdf/cop13/WHR?C_Amazon_REDD.pdf Accessed: 2012 Apr.
[43]
ter Steege H, Pitman NCA, Phillips OL, Chave J, Sabatier D, et al. (2006) Continental-scale patterns of canopy tree composition and function across Amazonia, Nature, 443, 444–447:
[44]
Baker TR, Phillips OL, Laurance WF, Pitman NCA, Almeida S, et al. (2009) Do species traits determine patterns of wood production in Amazonian forests? Biogeosciences, 6, 297–307:
[45]
Saatchi SS, Houghton RA, Dos Santos Alvala RC, Soares JV, Yu Y (2007) Distribution of aboveground live biomass in the Amazon Basin, Global Change Biology, 13, 816–837:
[46]
Malhi Y, Baker T, Wright J, Phillips OL, Almeida S, et al. (2004) The above ground coarse wood productivity of 104 neotropical forest plots, Global Change Biology, 10, 563–591:
[47]
Malhi Y, Phillips OL, Lloyd J, Baker T, Wright J, et al. (2002) An international network to monitor the structure, composition and dynamics of Amazonian forests (RAINFOR), Journal of Vegetation Science, 13, 439–450:
[48]
Phillips OL, Baker L, Arroyo L, Higuchi N, Killeen TJ, et al. (2004) Pattern and process in Amazon tree turnover 1976–2001, Philosophical Transactions of the Royal Society London B, 359, 381–407:
[49]
Stephenson NL, Van Mantgem PJ (2005) Forest turnover rates follow global and regional patterns of productivity, Ecology Letters, 8, 524–531:
[50]
Quesada CA, Lloyd J, Schwarz M, Baker T, Phillips OL, et al. (2009) Regional and large scale patterns in Amazon forest structure and function are mediated by variations in soil physical and chemical properties, Biogeosciences Discussions, 6, 3993–4057:
[51]
Malhi Y, Wright J (2004) Spatial patterns and recent trends in the climate of tropical regions, Philosophical Transactions of the Royal Society London B, 359, 311–329:
[52]
Malhi Y, Wood D, Baker T, Wright J, Phillips OL, et al. (2006) The regional variation of aboveground live biomass in old-growth Amazonian forests, 12, 1107–1138:
