The Effect of Various Molotov Cocktails on Different Surfaces and Evaluation of Fire Changes

Yıl 2024, Cilt: 16 Sayı: 2, 24 - 33, 31.08.2024

Zeliha Yıldırım , Cem Uysal

https://doi.org/10.56484/iamr.1439171

Öz

Objective:Molotov cocktails are a classic homemade weapon used over the past 80 years; also known as gasoline bombs. However, there is not enough research in the literature. Molotov cocktail is classified as a mildly explosive substance. But a Molotov cocktail is not an explosive. This is a handmade lighter. It is used to set fire to targets in terrorist attacks.
Methods:In our study, classic homemade Molotov cocktails were used. Oil, diluent, sugar, cologne, epoxy resin, paraffin, egg white, liquid and solid detergent, bleach, wood glue were added to the mixture. Parameters such as burning temperature, burning time, glass and nail spreading diameter, and residues of the Molotov cocktail were investigated. The prepared molotov cocktails were broken on 5 different floors, and the effect of changing the floor on the parameters was investigated.
Results:In our study, 51 (59.3%) of 86 molotov cocktails were broken. Most of the destruction occurred in the wall. According to the results we obtained, a relationship was found between the content of the Molotov cocktail, the burning temperature and the time. It was found that the damage was increased with the addition of substances to the mixture.
Conclusion: In addition, in our study, it was noticed that the Molotov cocktail did not explode by itself and did not cause damage to the environment by throwing nails.

Anahtar Kelimeler

Molotov Cocktail, Terrorism, Explosives, Incendiaries

Destekleyen Kurum

Dicle Üniversitesi Bilimsel Araştırma Projeleri Birimi

Proje Numarası

TIP.22.009

Kaynakça

• Landau D. The Source of the Term Molotov Cocktail. Last updated: Feb 26, 2019; 3
• Kolaitis D.I. An experimental investigation of improvised incendiary devices used in urban riots: The “Molotov cocktail”. in Proceedings of the 2nd IAFSS European Symposium of Fire Safety Science, Nicosia, Cyprus. 2015.
• Serap died on the bus where Molotov was thrown. Access date: 11,07,2009. Available from: https://www.hurriyet.com.tr/gundem/molotof-atilan-otobuste-yanan-serap-oldu-13130045
• Jamaluddin M.I. Forensic Analysis of Gasoline in Molotov Cocktail Using Gas Chromatography-mass Spectrometry and Chemometric Procedures. 2014, University Sains Malaysia.
• Martín-Alberca C. et al., Anionic markers for the forensic identification of Chemical Ignition Molotov Cocktail composition. 2013. 53(1): 49-54.
• Luo Z. et al. Experimental study on the flammability limit parameters of premixed methanol-gasoline vapor-air mixtures. 2022: 104856.
• Stauffer E, Dolan J. A, Newman R. (2007). Fire debris analysis. Academic Press.
• Lee K. W. (2002). A methodology for assessing risk from released hydrocarbon in an enclosed area. Journal of Loss prevention in the process Industries, 15(1), 11-17.
• Hull T. R, Stec A. A. (2009). Polymers and fire.1-14
• Brown J. R, Mathys Z. (1997). Reinforcement and matrix effects on the combustion properties of glass reinforced polymer composites. Composites Part A: Applied Science and Manufacturing, 28(7), 675-681.
• Santoemma J. Wood glue. Access date: 02,25,1992. Available from: https://patents.google.com/patent/US5091458A/en
• 12. Robert, G. Capell, William P. Ridenour, John A Stewart. Paraffin wax compositions. Access date: 07,21,1953. Available from: https://patents.google.com/patent/US2636004A/en
• Balpetek F. G, Gülümser T. (2016). The effects of some components in household detergents on the whiteness of textile materials. Pamukkale University Journal of Engineering Sciences, 22(7), 597-604.
• Hazardous Substance Fact Sheet: Sodium Hypochlorite from September 2008.
• Silverstein T. P. (1998). The real reason why oil and water don't mix. Journal of chemical education, 75(1), 116.
• Thinner 435 Technical Data Sheet. Date: 28 March 2016 / Ver. 1.02
• Wallace L. A, Nelson W. C, Raymer J. H, Thomas K. W. (1991). Identification of polar volatile organic compounds in consumer products and common microenvironments. US Environmental Protection Agency, Office of Research and Development, Atmospheric Research and Exposure Assessment Laboratory.
• Mouritz A. P, Mathys Z, Gibson A. G. (2006). Heat release of polymer composites in fire. Composites Part A: Applied science and manufacturing, 37(7), 1040-1054.
• Juris, J. (2005). Violence performed and imagined. Critique of Anthropology, 25(4), 413-432. https://doi.org/10.1177/0308275x05058657
• Mandal, S., Song, G., Rossi, R., & Grover, I. (2021). Characterization and modeling of thermal protective fabrics under molotov cocktail exposure. Journal of Industrial Textiles, 51(1_suppl), 1150S-1174S. https://doi.org/10.1177/1528083720984973
• Kutmanaliev, J. (2015). Public and communal spaces and their relation to the spatial dynamics of ethnic riots. International Journal of Sociology and Social Policy, 35(7/8), 449-477. https://doi.org/10.1108/ijssp-02-2015-0027
• Akartuna, E. and Thornton, A. (2021). The kurdistan worker’s party (pkk) in london: countering overseas terrorist financing and support with “nudge” and situational approaches. Terrorism and Political Violence, 35(2), 470-496. https://doi.org/10.1080/09546553.2021.1941902