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New Forests

, Volume 47, Issue 3, pp 411–429 | Cite as

Ecological niche modelling of three Mediterranean pine species in the south of Spain: a tool for afforestation/reforestation programs in the twenty-first century

Article

Abstract

Climate change models predict an increase in aridity in many parts of the world for the twenty-first century, which is likely to be more intense in the Mediterranean basin than in other regions. This study addresses the potential distribution of three Mediterranean pine species (Pinus pinea L., P. halepensis Mill. and P. pinaster Aiton) in southern Spain in response to the forecast increased aridity. Pines constitute a useful source of various types of raw materials, which has led to their increasing introduction around the world. The study was based on ecological niche modelling using multinomial logistic regression, over an area spanning about 8.7 million ha in the south of Spain. In total, 11 explanatory variables were included, drawing on measurements made at high resolution (200 m). Four different periods were studied: the reference period (1961–2000), early twenty-first century (2011–2040), middle twenty-first century (2041–2070) and late twenty-first century (2071–2100). Future time slices were analysed in three different scenarios: B1, A1b and A2 in the CNCM3 general circulation model. The results predict a wider distribution for stone pine, which could expand its potential area in southern Spain. In contrast, Aleppo pine, and especially cluster pine, would reduce their present distribution, with cluster pine occupying higher altitude sites while low altitude populations diminished. The validation model enables accurate maps to be produced, representing powerful tools for afforestation/reforestation programs in the future.

Keywords

Ecological niche modelling Global change Multinomial logistic regression Mediterranean pines Southern Spain Afforestation/reforestation programs 

Notes

Acknowledgments

The authors are grateful to the Council of Economy, Innovation, Science and Employment of the Andalusian Regional Government for supporting this study in the framework of the project ‘‘Modelo espacial de distribución de las quercíneas y otras formaciones forestales de Andalucía: una herramienta para la gestión y la conservación del patrimonio natural” (Code P10-RNM-6013). This is the contribution no. 115 from the CEIMAR Journal Series.

Supplementary material

11056_2015_9523_MOESM1_ESM.tif (2.7 mb)
ESM 1 Additional information on comparative areas between the reference period and each scenario is shown for stone pine. Only cells with a probability over 0.5 (as percentage next to each map) were taken into account. Green corresponds to area gained, purple indicates lost areas and blue shows stable areas. White denotes the absence of suitability for both period and scenario (TIFF 2767 kb)
11056_2015_9523_MOESM2_ESM.tif (3.5 mb)
ESM 2 Additional information on comparative areas between the reference period and each scenario is shown for Aleppo pine. For details, see caption to ESM 1 (TIFF 3540 kb)
11056_2015_9523_MOESM3_ESM.tif (1002 kb)
ESM 3 Additional information on comparative areas between the reference period and each scenario is shown for cluster pine. For details, see caption to ESM 1 (TIFF 1001 kb)

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© Springer Science+Business Media Dordrecht 2015

Authors and Affiliations

  1. 1.Department of Environmental Biology and Public Health, Faculty of Experimental Sciences, International Campus of Excellence of the Sea (CEIMAR)University of HuelvaHuelvaSpain

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