Abstract
The evolution of the fireball resulting from the August 2020 Beirut explosion is traced using amateur videos taken during the first 400 ms after the detonation. Thirty-nine frames separated by 16.66–33.33 ms are extracted from six different videos located precisely on the map. Time evolution of the shock wave radius is traced by the fireball at consecutive time moments until about t approx 170 ms and a distance d approx 128 m. Pixel scales for the videos are calibrated by de-projecting the existing grain silos building, for which accurate as-built drawings are available, using the length, the width, and the height and by defining the line-of-sight incident angles. In the distance range d approx 60–128 m from the explosion center, the evolution of the fireball follows the Sedov–Taylor model with spherical geometry and an almost instantaneous energy release. This model is used to derive the energy available to drive the shock front at early times. Additionally, a drag model is fitted to the fireball evolution until its stopping at a time t approx 500 ms at a distance d approx 145pm 5 m. Using the derived TNT equivalent yield, the scaled stopping distance reached by the fireball and the shock wave-fireball detachment epoch within which the fireball is used to measure the shock wave are in excellent agreement with other experimental data. A total TNT equivalence of 200pm 80,mathrm{t} at a distance d approx 130 m is found. Finally, the dimensions of the crater size taken from a hydrographic survey conducted 6 days after the explosion are scaled with the known correlation equations yielding a close range of results. A recent published article by Dewey (Shock Waves 31:95–99, 2021) shows that the Beirut explosion TNT equivalence is an increasing function of distance. The results of the current paper are quantitatively in excellent agreement with this finding. These results present an argument that the actual mass of ammonium nitrate that contributed to the detonation is much less than the quantity that was officially claimed available.
Highlights
On August 4, 2020, an explosion occurred in the port of Beirut, Lebanon, after a fire ignited in warehouse number 12
Once the shock wave reaches the outer boundary of the burning fuel, it will be transmitted to the surrounding medium and will propagate isotropically in the form of a blast wave
The fireball cannot trace the shock wave at all times; we provide scaling arguments that the epoch within which we use the fireball as a representative of the shock wave and their detachment time are valid
Summary
On August 4, 2020, an explosion occurred in the port of Beirut, Lebanon, after a fire ignited in warehouse number 12. This tragic event resulted in massive large-scale destruction, severe damage to the buildings in an extended radius around the center, and loss of lives. A few attempts were made to quantify the amplitude of this explosion Several of these studies used the time-ofarrival of the shock wave (from audio and visual inspection of footage) up to distances ranging from 500 to about 2000 m [1,2,3]. These studies used empirical relations linking the scaled time-of-arrival with the scaled distance to report a TNT equivalence range of 0.3–1.1 kt
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