Fires is one of the main types of disturbances that
shape ecosystems in the Mediterranean region. However nowadays,
climate alterations towards higher temperatures result on increased
levels of fire intensity, frequency and spread as well as difficulties for
natural regeneration to occur. Thasos Island is one of the Greek
islands that has experienced those problems. Since 1984, a series of
wildfires led to the reduction of forest cover from 61.6% to almost
20%. The negative impacts were devastating in many different
aspects for the island. The absence of plant cover, post-wildfire
precipitation and steep slopes were the major factors that induced
severe soil erosion and intense floods. That also resulted to serious
economic problems to the local communities and the inability of the
burnt areas to regenerate naturally. Despite the substantial amount of
published work regarding Thasos wildfires, there is no information
related to post-wildfire effects on factors such as soil erosion. More
research related to post-fire effects should help to an overall
assessment of the negative impacts of wildfires on land degradation
through processes such as soil erosion and flooding.
[1] Papanastasis, V. 1978. Potential of certain range species for
improvement of burned brushland in Greece. Proc.1st International
Rangeland Congress, pp.715-717.
[2] Arianoutsou, M., Papanastasis, V. P. (2004) Ecology, Conservation and
Management of Mediterranean Climate Ecosystems. Millpress,
Rotterdam.
[3] Espirito-Santo, M. D., Rego, F., Costa, J. C. (1993) Vegetation
dynamics in the Serra dos Canderros (Central Portugal). In: Fire in
Mediterranean Ecosystems (edited by L. Trabaud and R. Prodon). Ecosystem Research Report no 5, Commission of the European
Communities. Brussels - Luxembourg, pp: 29-46.
[4] Ispikoudis, I., Kakouros, P., Arianatsou, M., Papanastasis, V.P. (1999)
Effects of pastoral activities on woody plant distribution and landscape
diversity in Western Crete. In: V.P. Papanastasis, J. Frame and A.S.
Nastis (Eds), Grasslands and Woody Plants in Europe, pp 287-293,
EGF, Grassland Science in Europe, Thessaloniki and Reading, 437p.
[5] Naveh, Z. (1991) The role of fire in Mediterranean vegetation. Botanica
Chronika 10: 385-405.
[6] Mendoza, I., Zamora, R., Castro, J. (2009) A seedling experiment for
testing tree community recruitment under variable environments:
Implications for forest regeneration and conservation in Mediterranean
habitats. Biological Conservation, 142, pp. 1401-1499.
[7] Sharma, S., Rikhari, H. C. (1997) Forest fire in the central Himalaya:
climate and recovery of trees. Int J Biometeorol. 40: 63-70.
[8] Lekakis, J. (1993) Social and ecological correlates of rural fires in
Greece. Journal of Environmental Management 43: 41-47.
[9] Spanos, I., Daskalakou, E., Thanos, K. (2000) Postfire regeneration in
Pinus brutia forest ecosystems of Thassos island. Acta Oecologica, 21,
pp. 13-20.
[10] Bestmann, M., Kunze, K., Matthews, A. (2000) Evolution of a calcite
marble shear zone complex on Thassos Island, Greece: Microstructural
and textural fabrics and their kinematic significance. Journal of
Structural Geology, 22, pp. 1789–1807.
[11] Campbell, R. E., Baker, M. B., Fiolliott, P. F., Larson, F.R., Avery, C.
C. (1977) Wildfire Effects on a Ponderosa Pine Ecosystem: An Arizona
Case Study. United States Department of Agriculture Forest Service,
Rocky Mountain Forest and Range Experimental Station, Fort Collins,
Colorado. Research Paper RM-191, 21 pp.
[12] Trabaud, L. (2002) Post-fire vegetation recovery and dynamics in the
Mediterranean area. In: Pardini, G., Pinto, J. (Eds.), Fire, Landscape and
Biodiversity: an Appraisal of the Effects and Effectiveness. UdG,
Girona, Diversitas, pp. 39–55.
[13] DeBano, L. F., Neary, D. G., Folliott, P. F. (2005) Soil physical
properties. In: Neary, D. G., Ryan, K. C., DeBano, L. F. (Eds.),
Wildland Fire in Ecosystems. Effects of Fire on Soil and Water. General
Technical Report RMRS-GTR-42, Volume 4. USDA Forest Service,
Rocky Mountain Research Station, pp. 29–52.
[14] Robichaud, P. R. (2000) Fire effects on infiltration rates after prescribed
fire in Northern Rocky Mountain forests, USA. Journal of Hydrology,
231–232, pp. 220–229.
[15] Woods, S. W., Balfour, V. N. (2008) The effect of ash on runoff and
erosion after a severe forest wildfire, Montana, USA. International
Journal of Wildland Fire, 17, pp. 535–548.
[16] Cerdà, A., Robichaud, P. R. (2009) Fire Effects on Soils and Restoration
Strategies. Science Publishers, Enfield, NH. 569 pp.
[17] Shakesby, R. A., Doerr, S. H. (2006) Wildfire as a hydrological and
geomorphological agent. Earth Science Reviews, 74, pp. 269–307.
[18] Ursino, N., Rulli, M. C. (2010) Combined effect of fire and water
scarcity on vegetation patterns in arid lands. Ecological Modelling, 221,
pp. 2353–2362.
[19] Loaiciga, H. A., D. Pedreros and D. Roberts. 2001. Wildfire–streamflow
interactions in a chaparral watershed. Advances in Environmental
Research, 5, pp. 295–305.
[20] Rubio, J. L., Forteza, J., Andreu, V., Cerni, R. (1997) Soil profile
characteristics influencing runoff and soil erosion after forest fire: a case
study (Valencia, Spain). Soil Technology 11: 67–78.
[21] Martin, D. A., Moody, J. A. (2001) Comparison of soil infiltration rates
in burned and unburned mountainous watersheds. Hydrological
Processes, 15, pp. 2893–2903.
[22] Rodríguez Avellanas, J. M., Vicén Velilla, F. J., Badía Villas, D.,
Ascaso Martorell, J. (2000) Efecto del incendio forestal sobre la
sucesión vegetal y erosión en los montes de Castejón de Valdejasa
(Zaragoza). Geórgica, 7, pp. 55–68.
[23] Vega, J. A., Díaz-Fierros, F. (1987) Wildfire effects on soil erosion.
Ecologia Mediterranea, 13 (4), pp. 119–125.
[24] Connaughton, C. A. (1935) Forest fire and accelerated erosion. Journal
of Forestry, 33, pp. 751–752.
[1] Papanastasis, V. 1978. Potential of certain range species for
improvement of burned brushland in Greece. Proc.1st International
Rangeland Congress, pp.715-717.
[2] Arianoutsou, M., Papanastasis, V. P. (2004) Ecology, Conservation and
Management of Mediterranean Climate Ecosystems. Millpress,
Rotterdam.
[3] Espirito-Santo, M. D., Rego, F., Costa, J. C. (1993) Vegetation
dynamics in the Serra dos Canderros (Central Portugal). In: Fire in
Mediterranean Ecosystems (edited by L. Trabaud and R. Prodon). Ecosystem Research Report no 5, Commission of the European
Communities. Brussels - Luxembourg, pp: 29-46.
[4] Ispikoudis, I., Kakouros, P., Arianatsou, M., Papanastasis, V.P. (1999)
Effects of pastoral activities on woody plant distribution and landscape
diversity in Western Crete. In: V.P. Papanastasis, J. Frame and A.S.
Nastis (Eds), Grasslands and Woody Plants in Europe, pp 287-293,
EGF, Grassland Science in Europe, Thessaloniki and Reading, 437p.
[5] Naveh, Z. (1991) The role of fire in Mediterranean vegetation. Botanica
Chronika 10: 385-405.
[6] Mendoza, I., Zamora, R., Castro, J. (2009) A seedling experiment for
testing tree community recruitment under variable environments:
Implications for forest regeneration and conservation in Mediterranean
habitats. Biological Conservation, 142, pp. 1401-1499.
[7] Sharma, S., Rikhari, H. C. (1997) Forest fire in the central Himalaya:
climate and recovery of trees. Int J Biometeorol. 40: 63-70.
[8] Lekakis, J. (1993) Social and ecological correlates of rural fires in
Greece. Journal of Environmental Management 43: 41-47.
[9] Spanos, I., Daskalakou, E., Thanos, K. (2000) Postfire regeneration in
Pinus brutia forest ecosystems of Thassos island. Acta Oecologica, 21,
pp. 13-20.
[10] Bestmann, M., Kunze, K., Matthews, A. (2000) Evolution of a calcite
marble shear zone complex on Thassos Island, Greece: Microstructural
and textural fabrics and their kinematic significance. Journal of
Structural Geology, 22, pp. 1789–1807.
[11] Campbell, R. E., Baker, M. B., Fiolliott, P. F., Larson, F.R., Avery, C.
C. (1977) Wildfire Effects on a Ponderosa Pine Ecosystem: An Arizona
Case Study. United States Department of Agriculture Forest Service,
Rocky Mountain Forest and Range Experimental Station, Fort Collins,
Colorado. Research Paper RM-191, 21 pp.
[12] Trabaud, L. (2002) Post-fire vegetation recovery and dynamics in the
Mediterranean area. In: Pardini, G., Pinto, J. (Eds.), Fire, Landscape and
Biodiversity: an Appraisal of the Effects and Effectiveness. UdG,
Girona, Diversitas, pp. 39–55.
[13] DeBano, L. F., Neary, D. G., Folliott, P. F. (2005) Soil physical
properties. In: Neary, D. G., Ryan, K. C., DeBano, L. F. (Eds.),
Wildland Fire in Ecosystems. Effects of Fire on Soil and Water. General
Technical Report RMRS-GTR-42, Volume 4. USDA Forest Service,
Rocky Mountain Research Station, pp. 29–52.
[14] Robichaud, P. R. (2000) Fire effects on infiltration rates after prescribed
fire in Northern Rocky Mountain forests, USA. Journal of Hydrology,
231–232, pp. 220–229.
[15] Woods, S. W., Balfour, V. N. (2008) The effect of ash on runoff and
erosion after a severe forest wildfire, Montana, USA. International
Journal of Wildland Fire, 17, pp. 535–548.
[16] Cerdà, A., Robichaud, P. R. (2009) Fire Effects on Soils and Restoration
Strategies. Science Publishers, Enfield, NH. 569 pp.
[17] Shakesby, R. A., Doerr, S. H. (2006) Wildfire as a hydrological and
geomorphological agent. Earth Science Reviews, 74, pp. 269–307.
[18] Ursino, N., Rulli, M. C. (2010) Combined effect of fire and water
scarcity on vegetation patterns in arid lands. Ecological Modelling, 221,
pp. 2353–2362.
[19] Loaiciga, H. A., D. Pedreros and D. Roberts. 2001. Wildfire–streamflow
interactions in a chaparral watershed. Advances in Environmental
Research, 5, pp. 295–305.
[20] Rubio, J. L., Forteza, J., Andreu, V., Cerni, R. (1997) Soil profile
characteristics influencing runoff and soil erosion after forest fire: a case
study (Valencia, Spain). Soil Technology 11: 67–78.
[21] Martin, D. A., Moody, J. A. (2001) Comparison of soil infiltration rates
in burned and unburned mountainous watersheds. Hydrological
Processes, 15, pp. 2893–2903.
[22] Rodríguez Avellanas, J. M., Vicén Velilla, F. J., Badía Villas, D.,
Ascaso Martorell, J. (2000) Efecto del incendio forestal sobre la
sucesión vegetal y erosión en los montes de Castejón de Valdejasa
(Zaragoza). Geórgica, 7, pp. 55–68.
[23] Vega, J. A., Díaz-Fierros, F. (1987) Wildfire effects on soil erosion.
Ecologia Mediterranea, 13 (4), pp. 119–125.
[24] Connaughton, C. A. (1935) Forest fire and accelerated erosion. Journal
of Forestry, 33, pp. 751–752.
@article{"International Journal of Earth, Energy and Environmental Sciences:71326", author = "George D. Ranis and Valasia Iakovoglou and George N. Zaimes", title = "Ecosystem Post-Wildfire Effects of Thasos Island", abstract = "Fires is one of the main types of disturbances that
shape ecosystems in the Mediterranean region. However nowadays,
climate alterations towards higher temperatures result on increased
levels of fire intensity, frequency and spread as well as difficulties for
natural regeneration to occur. Thasos Island is one of the Greek
islands that has experienced those problems. Since 1984, a series of
wildfires led to the reduction of forest cover from 61.6% to almost
20%. The negative impacts were devastating in many different
aspects for the island. The absence of plant cover, post-wildfire
precipitation and steep slopes were the major factors that induced
severe soil erosion and intense floods. That also resulted to serious
economic problems to the local communities and the inability of the
burnt areas to regenerate naturally. Despite the substantial amount of
published work regarding Thasos wildfires, there is no information
related to post-wildfire effects on factors such as soil erosion. More
research related to post-fire effects should help to an overall
assessment of the negative impacts of wildfires on land degradation
through processes such as soil erosion and flooding.", keywords = "Erosion, land degradation, Mediterranean islands,
regeneration, Thasos, wildfires.", volume = "9", number = "10", pages = "1264-4", }
