Effect of Slope on the Analysis of Forest Fire Risk

Year 2020, Volume: 48 Issue: 4, 373 - 379, 06.07.2020

Uğur Baltacı Feriha Yıldırım

https://doi.org/10.15671/hjbc.753080

Cited By: 2

Abstract

The main cause of forest fires is human activities. For this reason, when talking about the risk of forest fire in an area, it is mentioned about the intensity of human activities that can cause forest fire when vegetation and topographic compatibility are provided. In other words, although the type, amount, humidity and intensity of the combustible material is suitable with the effect of topographic factors in an area, if there is no human activity that will cause fire, only lightning caused forest fires can be mentioned. While evaluating the impact of slope on forest fire risk in our study, the starting points of the last 10 years forest fires have occurred in Turkey were analyzed with geographic information systems (GIS). Thus, it has been tried to make an objective assessment of the impact of the slope on forest fire risk. According to the results of the analysis, 40.53% of the forest fires which examined in Turkey occured in the range of slope between 0-10%. Therewithal, 87.16% of these fires occured in the range of slope between 0-30%. As a result, contrary to the general opinion, it is thought that the forest fire risk decrease as the slope increases.

Keywords

: Forest fire risk, risk index, slope, GIS

References

• Archibald, S., Lehmann, C. E. R., Gómez-Dans, J. L., Bradstock, R. A., Defining pyromes and global syndromes of fire regimes, Proceedings of the National Academy of Sciences, 110 (2013) 6442–6447.
• Doussi, M.A., Thanos, C.A., Postfire regeneration of hardseeded plants: Ecophysology of seed germination, Proceedings of the 2nd International Conference of Forest Fire Research, Coimbra, 25(2) (1994) 1035-1044.
• Moreira, F., Vallejo, R., What to do after fire? Post-fire restoration. In Birot, Y., (ed.), Living with Wild fires: What science can tell us, A contribution to the science – Policy dialoque, EFI Discussion Paper, 15 (2009) 53-58.
• Pausas, J. G., Changes in fire and climate in the eastern Iberian Peninsula (Mediterranean basin), Climatic Change, 63 (2004) 337-350.
• Pausas, J. G., Keeley, J. E., Abrupt climate-independent fire regime changes, Ecosystems, 17 (2014) 1109-1120.
• Tavşanoğlu, Ç., Yangın coğrafyası: Vejetasyon yangınlarının ve ekolojik sonuçlarının alansal dağılımı, Kebikeç, 43 (2017) 289-300.
• Ogm(a), 2010-2019 yılları arasında meydana gelen orman yangınlarının çıkış sebeplerine dağılımı, Orman Yangınları Değerlendirme Raporu, OGM Orman Yangınlarıyla Mücadele Daire Başkanlığı, (2020) 48.
• Bilgili, E., Sağlam, B., Başkent, Z. E., Yangın Amenajmanı Planlamalarında Yangın Tehlike Oranları ve Coğrafi Bilgi Sistemleri, Fen ve Mühendislik Dergisi, 4(2) (2001), 88-97.
• Van Wilgen, B., W., Burgan, R., E., Adaptation of The United States Fire Danger Rating System to Fynbos Conditions, Part II, Historic Fire Danger in the Fynbos Biome, South African Forestry Journal, 129 (1984) 66-78.
• Taylor, S., W., Alexander, M., E., Considerations in Developing a National Forest Fire Danger Rating System, Paper Presented at the XII World Forestry Congress, Quebec, Canada, (2003).
• Jaiswal, R.K., Mukherjee, S., Raju, D.K., Saxena, R., Forest fire risk zone mapping from satellite imagery and GIS, Int Journal of Applied Earth Observation and Geoinformation, 4 (2002) 1-10.
• Neyişçi, T., Ayaşlıgil, Y., Ayaşlıgil, T., Sönmezışık, T., Yangına dirençli orman kurma ilkeleri, Tubitak-Togtag-1342, TMMOB Orman müh. Odası yayınları, 21 (1999).
• Çanakçıoğlu, H., Orman Koruma Ders Kitabı, İ.Ü. Orman Fakültesi yayın no 411/3524 (1993).
• Hayli, S., Canpolat F. A., Türkiye’de kırsal yerleşmelerin kuruluş ve gelişmesinde etkili olan faktörlere teorik bir yaklaşım, Zeitschrift Für Die Welt Der Türken, 10(2) (2018) 183-206.
• Ogm(b), Son 10 yıllık (2010-2019) yangın sıralacı, Orman yangınlarıyla mücadele daire başkanlığı veri tabanı, OGM Orman Yangınlarıyla Mücadele Daire Başkanlığı, (2020).
• Erten, E., Kurgun, V., Musaoglu, N., Forest fire risk zone mapping from satellite imagery and GIS: A case study, Proceedings of XX.th Congress of ISPRS, Turkey, (2004) 12-25.
• Erten, E., Kurgun, V., Musaoğlu, N., Uzaktan Algılama ve Coğrafi Bilgi Sistemleri Kullanarak Orman Yangını Bilgi Sisteminin Kurulması, Proceedings of TMMOB harita ve kadastro mühendisleri odası 10. Türkiye harita bilimsel ve teknik kurultayı, (2005).
• Sağlam, B., Ertuğrul, B., Durmaz, B.D., Kadıoğulları, A.İ., Küçük, Ö., Spatio-temporal analysis of forest fire risk and danger using LANDSAT imagery, Sensors, 8 (2008) 3970-3987.
• Cipriani, H.N., Pereira, J.A.A., Silva, R.A., Freitas, S.G., Oliveira, L.T., Fire risk map for the Serra de São Domingos Municipal Park, Poços de Caldas, CERNE, 17(1) (2011) 77-83.
• Adab, H., Kanniah, K.D., Solaimani, K., Modeling forest fire risk in the northeast of İran using remote sensing and GIS techniques, Nat Hazards, 65(3) (2013) 1723-1743.
• Sivrikaya, F., Akay, A.E., Oğuz, H., Yenilmez, N., Mapping forest fire danger zones using GIS: A case study from Kahramanmaraş, 6th International Symposium on Ecology and Environmental Problems, 17-20 November, Antalya, (2011).
• Karabulut, M., Karakoç, A., Gürbüz, M. ve Kızılelma, Y., Determination of forest fire risk areas in Başkonuş Mountain (Kahramanmaraş) using geographical ınformation systems, Int Soc Res J., 6 (2013) 171-179.
• Akay, A.E., Şahin, H., Forest Fire Risk Mapping by using GIS Techniques and AHP Method: A Case Study in Bodrum (Turkey), Eur J Forest Eng, 5(1) (2019) 25-35.
• Andrews, P.L., Chase, C.H., Fire behavior prediction and fuel modeling system. USDA Forest Service, General Technical Report INT-260, Utah, (1989).
• Teie, C.W., Fire Officier's Handbook on Wildland Firefighting, Deer Valley Press Rescue, California, (1997).
• Perry, D.G., Wildland Firefighting. Fire Behavior, Tactics and Command. Fire Publications, Inc. California, (1990).