Asympathetic detonation (SD, or SYDET), also called flash over, is a detonation, usually unintended, of an explosive charge by a nearby explosion. Sympathetic detonation is caused by a shock wave, or impact of primary or secondary blast fragments.
The initiating explosive is called donor explosive, the initiated one is known as receptor explosive. In case of a chain detonation, a receptor explosive can become a donor one.
The shock sensitivity, also called gap sensitivity, which influences the susceptibility to sympathetic detonations, can be measured by gap tests.
Ifdetonators with primary explosives are used, the shock wave of the initiating blast may set off the detonator and the attached charge. However even relatively insensitive explosives can be set off if their shock sensitivity is sufficient. Depending on the location, the shock wave can be transported by air, ground, or water. The process is probabilistic, a radius with 50% probability of sympathetic detonation often being used for quantifying the distances involved.
Sympathetic detonation presents problems in storage and transport of explosives and ordnance. Sufficient spacing between adjanced stacks of explosive materials has to be maintained.[1] In case of an accidental detonation of one charge, other ones in the same container or dump can be detonated as well, but the explosion should not spread to other storage units. Special containers attenuating the shock wave can be used to prevent the sympathetic detonations; epoxy-bonded pumice liners were successfully tested.[2] Blow-off panels may be used in structures, e.g. tank ammunition compartments, to channel the explosion overpressure in a desired direction to prevent a catastrophic failure.
Other factors causing unintended detonations are e.g. flame spread, heat radiation, and impact of shrapnels.
Cf. cooking off, setting off an explosive by subjecting it to sustained heat of e.g. a fire or a hot gun barrel. A cooked-off explosive may cause sympathetic detonation of adjanced explosives.
Sympathetic detonations may occur in munitions stored in e.g. vehicles, ships, gun mounts, or storage depots, by a sufficiently close explosion of a projectile or a bomb. Such detonations after receiving a hit caused many catastrophical losses.
To prevent sympathetic detonations, minimal distances (specific for a given typ of the mine) have to be maintained between mines when laying a minefield.
Spallation of materials after an impact on the opposite side may create fragments capable of causing sympathetic detonations of stored explosives on the opposite side of an armour plate or a concrete wall.[3] Transfer of the shock wave through the wall or armour may also be possible cause of a sympathetic detonation.
Solid rocket fuels of the class 1.1 are susceptible to sympathetic detonation. Conversely, fuels of the class 1.3 can be ignited by a nearby fire or explosion but aren't likely to detonate. The 1.1 fuels however tend to have slightly higher specific impulse, and therefore are used in those military applications where weight and/or size is at premium, e.g. on ballistic and cruise missile submarines.[4]
Sympathetic detonation can be used for destroying of e.g. unexploded ordnance, improvised explosive devices, land mines, or naval mines by an adjanced bulk charge.
Special insensitive explosives, e.g. TATB, are used in e.g. military applications to prevent the sympathetic detonations.
During the 1967 USS Forrestal fire, eight old Composition B based iron bombs cooked off. The last one caused a sympathetic detonation of a ninth bomb, a more modern and less cookoff-susceptible Composition H6 based one.
The Russian submarine Kursk explosion was probably caused by a sympathetic explosion of several torpedo warheads. A single dummy torpedo VA-111 Shkval exploded; 135 seconds later a number of warheads simultaneously exploded and sunk the submarine.
Inrock blasting, sympathetic detonations occur when the blastholes are sufficiently close to each other, usually 57 mm or less, and especially in rocks that poorly attenuate the shock energy. Ground water in open channels facilitates sympathetic detonation as well. Blasthole spacing of 300 or more millimeters is suggested. However, in some ditch blasting cases sympathetic detonations are exploited purposefully.[5] Nitroglycerine-based explosives are especially susceptible. Picric acid is sensitive as well. [6] Water gel explosives, slurry explosives, and emulsion explosives tend to be insensitive to sympathetic detonations. For most industrial explosives, the maximum distances for possible sympathetic detonations are between 2-8 times of the charge diameter.[7] Uncontrolled sympathetic detonations may cause excessive ground vibrations and/or flying rocks.
The spread of shock waves can be hindered by placing relief holes - drilled holes without explosive charges - between the blastholes.[6]
The opposite phenomenon is dynamic desensitization. Some explosives, e.g. ANFO, show reduced sensitivity under pressure. A transient pressure wave from a nearby detonation may compress the explosive sufficiently to make its initiation fail. This can be prevented by introducing sufficient delays into the firing sequence.[6]
A sympathetic detonation during mine blasting may influence the seismic signature of the blast, by boosting the P-wave amplitude without significantly amplifying the surface wave.[8]
