Global Journal of Human-Social Science, B: Geography, Environmental Science and Disaster Management, Volume 22 Issue 3

2. Abreu, M. M., Santos, E. S., Ferreira, M. & Magalhães, M. C. F. (2012). Cistus salviifolius a promising species for mine wastes remediation. Journal of Geochemical Exploration, 113, 86-93. doi: 10.1016/j.gexplo.2011.03.007 3. Alcoba, P., González, E., Martínez, S., Martínez, L., Pérez, V., Martínez, M.J., Pérez, C. (2014). Transferencia de elementos traza suelo-planta en suelos con influencia salina. Congreso Nacional de Medio Ambiente (CONAMA). 4. Ashraf, M.A., Hussain, I., Rasheed, R., Iqbal, M., Riaz, M., Arif, M.S. (2017). Advances in microbe- assisted reclamation of heavy metal contaminated soils over the last decade: a review. Journal of environmental management, 198, 132-143. 5. Baker, A. J. & Walker, P. L. (1990). Ecophysiology of metal uptake by tolerant plants. Heavy metal tolerance in plants: evolutionary aspects, 2, 155- 165. 6. Chatterjee, C., Gopal, R. & Dube, B. K. (2006). Physiological and biochemical responses of French bean to excess cobalt. Journal of Plant Nutrition, 29 (1), 127-136. doi: 10.1080/01904160500416513 7. Corral, M. (2021). Especies Exóticas Invasoras: Caso de Ailanthus altissima (Mill.) Swingle en el centro de la península ibérica. Tesis Doctoral. UAM. 8. Corral, M. (2022). Factor bioconcentración en Ailanthus altissima (Mill.) Swingle. Análisis preliminar. Cuadernos Geográficos, 61(1), 189-205. 9. Corral, M., de Soto, I.S., Fidalgo, C., García,R. (2022). Soil chemistry and expansion of Ailanthus altissima (Mill.) Swingle. XIII Congreso Nacional y XIII Congreso Ibérico de Geoquímica. Puertollano, 25-27 abril 2022 10. Dzier ż anowski, K., Popek, R., Gawro ń ska, H., Sæbø, A. & Gawro ń ski, S. W. (2011). Deposition of particulate matter of different size fractions on leaf surfaces and in waxes of urban forest species. International Journal of Phytoremediation, 13 (10), 1037-1046. doi: 10.1080/15226514.2011.552929 11. Enríquez de Salamanca, A. (2020). La invasión de Ailanthus Altissima (Mill.) swingle en Madrid. Flora Montiberica 76, 4-14. 12. Gassó N., Thuiller W., Pino J. & Vilà M. (2012). Potential distribution range of invasive plant species in Spain. Neobiota 12. 25-40. 13. Gutiérrez-López, M., Ranera, E., Novo, M., Fernández, R., Trigo, D. (2014). Does the invasion of the exotic tree Ailanthus altissima affect the soil arthropod community? The case of a riparian forest of the Henares River (Madrid). European Journal of Soil Biology 62, 39-48. 14. Hu, S. Y. (1979). Ailanthus. Arnoldia, 39(2), 29-50. 15. Hu, Y., Wang, D., Wei, L. & Song, B. (2014). Heavy metal contamination of urban topsoils in a typical region of Loess Plateau, China. Journal of soils and sediments, 14(5), 928-935. doi: 10.1007/s11368- 013-0820-1. 16. Hu, Y., Wang, D., Wei, L., Zhang, X., Song, B. (2014). Bioaccumulation of heavy metals in plant leaves from Yan ׳ an city of the Loess Plateau, China. Ecotoxicology and environmental safety, 110, 82-88. 17. Huang, Y., Ai, X., Yao, L., Zang, R., Ding, Y., Huang, J., Feng & Liu, J. (2015). Changes in the diversity of evergreen and deciduous species during natural recovery following clear-cutting in a subtropical evergreen-deciduous broadleaved mixed forest of central China. Tropical Conservation Science, 8(4), 1033-1052. 18. Kleckerová, A., Očekalová, H. (2014). Andelion plants as a biomonitor of urban area contamination by heavy metals. International Journal of Environmental Research, 8 (1), 157-164. 19. Knüsel, S., Liu, J., Conedera, M., Gärtner, H., Bugmann, H., Li, M., Stoffel, M & Wunder, J. (2019). Comparative dendroecological characterisation of Ailanthus altissima (Mill.) Swingle in its native and introduced range. Dendrochronologia, 57, 125-608. 20. Kovacs, M., Opauszky, I., Klincsek, P.K. & Podani, J. (1982). The leaves of city trees as accumulation indicators. In: Steubing, L.S., Jäger, H.J. (Eds.), Monitoring of Air Pollutants by Plants. Methods and Problems. Dr. W. Junk, The Hague, 149–153 21. Kowarik, I. & Böcker, R. (1984). Zur Verbreitung, Vergesellschaftung und Einbürgerung des Götterbaumes (Ailanthus altissima [Mill.] Swingle) in Mitteleuropa. Tuexenia, 4. 22. Kowarik, I. & Säumel, I, (2007). Biological flora of Central Europe: Ailanthus altissima (Mill.) Swingle. Perspect. Plant Ecology Evolution System. 8(4), 207-237. 23. Kumar, S. (2013). Appraisal of heavy metal concentration in selected vegetables exposed to different degrees of pollution in Agra, India. Environmental monitoring and assessment, 185 (3), 2683-2690. 24. Lebrun, M., Alidou Arzika, I., Miard, F., Nandillon, R., Bayçu, G., Bourgerie, S., Morabito, D. (2020). Effect of fertilization of a biochar and compost amended technosol: Consequence on Ailanthus altissima growth and As- and Pb-specific root sorption. Soil Use Management 36, 766–772. 25. Lin, L., Yan, J., Ma, K., Zhou, W., Chen, G., Tang, R., Zhang, Y. (2017). Characterization of particulate matter deposited on urban tree foliage: A landscape analysis approach. Atmospheric Environment, 171, 59-69. 26. Lin, L., Yan, J., Ma, K., Zhou, W., Chen, G., Tang, R., Zhang, Y. (2017). Characterization of particulate matter deposited on urban tree foliage: A landscape analysis approach. Atmospheric Environment, 171, 59-69. Volume XXII Issue III Version I 6 ( ) Global Journal of Human Social Science - Year 2022 © 2022 Global Journals B Ailanthus Altissima (Mill.) Swingle, Bioacumulated Specie of Contaminated Soils