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Investigation of concentration limits of flame propagation in ammonia-based gas mixtures
Yu. N. Shebeko, A. V. Trunev, S. G. Tsarichenko, A. A. Zaitsev
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3–7 |
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A nonlinear model for hydrodynamic instability of an expanding flame
S. S. Minaev, E. A. Pirogov, O. V. Sharypov
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8–16 |
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Continuous detonation combustion of an annular gas-mixture layer
F. A. Bykovskii, E. F. Vedernikov
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17–20 |
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Use of a nozzle in particle acceleration by a flow of gas detonation products in tubes
V. V. Grigor'ev
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21–29 |
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Study of polymethyl methacrylate ignition and extinction on exposure to a high-power laser pulse
M. V. Alekseev, I. G. Fateev
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30–33 |
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General mathematical model for forest fires and its applications
A. M. Grishin
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35–54 |
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Mathematical modeling and predicting wildland fire effects
F. A. Albini, J. K. Brown
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55–70 |
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Iterative solution of the radiation transport equations governing spread of fire in wildland fuel
F. A. Albini
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71–82 |
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The boreal forest, fire, and the global climate system: Achievements and needs in joint East-West boreal fire research and policy development
J. G. Goldammer
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83–98 |
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Influence of moisture content and heat and mass exchange with the surrounding medium on the critical conditions of initiation of surface fire
A. I. Zvyagils'kaya, A. N. Subbotin
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99–106 |
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Ignition of forest tracts by a high-altitude source of radiant energy
A. M. Grishin, V. A. Perminov
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107–115 |
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Fires caused by nuclear explosions and their consequences
V. S. Pinaev, V. A. Shcherbakov
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116–121 |
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Investigation of optical characteristics and particle-size distribution of wood-smoke aerosols
V. S. Kozlov, M. V. Panchenko
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122–133 |
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Lightning as a source of forest fires
A. A. Dulzon
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134–142 |
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Experimental estimation of the strength of the coke of a charring, rubber-like, heat-shield material
G. V. Kuznetsov
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143–150 |
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