seismic bomb being handled at
RAF Woodhall Spa in Lincolnshire that was later dropped on the
La Coupole V-weapon site at
Wizernes, France, in 1944 An explosion in air does not transfer much energy into a solid, as their differing
acoustic impedances make an
impedance mismatch that reflects most of the energy. Due to the lack of bombing accuracy against anti-aircraft defences, air forces used
area bombardment, dropping large numbers of bombs to increase the likelihood that the target would be hit. Although a direct hit from a light bomb would destroy an unprotected target, it was comparatively easy to armour ground targets with many yards of concrete and thus render critical installations such as bunkers essentially bombproof. If the bomb could be designed to explode in water, soil, or other less compressible materials, the explosive force would be transmitted more efficiently to the target. Barnes Wallis' idea was to drop a large, heavy bomb with a hard-armoured tip at supersonic speed (as fast as an artillery shell) so that it would penetrate the ground like a ten-ton bullet fired straight down. It was then set to explode underground, ideally to the side of, or underneath, a hardened target. The resulting shock wave from the explosion would then produce a force equivalent to that of a 3.6 magnitude earthquake, destroying any nearby structures such as dams, railways, viaducts, etc. Any concrete reinforcement of the target would likely help enclose the force better. Wallis also argued that if the bomb penetrated deep enough, the explosion would not breach the surface of the ground and would thus produce a cavern (a
camouflet) that would remove the structure's underground support, causing it to collapse. The process was graphically described as a "trapdoor effect" or "hangman's drop". Wallis foresaw that disrupting German industry would remove its ability to fight, and also understood that
precision bombing was virtually impossible in the late 1930s. The technology for precision aiming was developed during World War II, and Barnes Wallis' ideas were then shown to be successful (see, for example, the
Bielefeld raid on 14 March 1945), considering the standards at the time. Wallis' first concept was for a ten-ton bomb that would explode at a depth of underground. To achieve this, the bomb would have had to be dropped from . The RAF had no aircraft at the time capable of carrying a ten-ton bomb load aloft, let alone lifting it to such a height. Wallis designed a six-engine aeroplane for the task, called the "
Victory Bomber", but there was no support for an aircraft with only a single purpose. Wallis then took a different line, developing a means to destroy Germany's industrial structure by attacking its hydroelectric power supply. After he had developed the
bouncing bomb and shown its possibilities,
RAF Bomber Command was prepared to listen to his other ideas, even though they often thought them strange. They provided enough support to let him continue his research. Later in the war, Barnes Wallis made bombs based on the "earthquake bomb concept", such as the 6-ton
Tallboy and then the 10-ton
Grand Slam, although these were never dropped from more than about . Even from this relatively low altitude, the earthquake bomb had the ability to disrupt German industry while causing minimal civilian casualties. It was used to disable the
V2 launch sites at
La Coupole and
Blockhaus d'Éperlecques, put out of action the
V-3 cannon sites at
Fortress of Mimoyecques, sink the
battleship Tirpitz and damage the
U-boats' protective pens at
St. Nazaire, as well as to attack many other targets which had been impossible to damage before. One of the most spectacular attacks was shortly after
D-Day, when the Tallboy was used to prevent German tank reinforcements from moving by train. Rather than blow up the tracks – which would have been repaired in a day or so – the bombs were targeted on a tunnel near
Saumur which carried the line under a mountain. Twenty-five Lancasters dropped the first Tallboys on the mountain, penetrating straight through the rock, and one of them exploded in the tunnel below. As a result, the entire rail line remained unusable until the end of the war. The
Bielefeld viaduct was only closed for brief periods by 54 raids dropping 3,500 tons, but in its first use on 14 March 1945, the "Grand Slam" destroyed whole sections of the viaduct. After World War II, the United States developed the
T12 demolition bomb, which was designed to create an earthquake effect. Given the availability of
nuclear weapons with
surface detonating
laydown delivery, there was little or no development of conventional deep penetrating bombs until the 1991
Gulf War. During the Gulf War, the need for a conventional deep penetrator became clear. In three weeks, a cooperative effort directed by the Armament Systems Division at
Eglin Air Force Base in Florida developed the
GBU-28 that was used successfully by
F-111Fs against a deep underground complex not far from
Baghdad just before the end of the war. The United States has developed a
Massive Ordnance Penetrator, designed to attack very deeply buried targets without the use of nuclear weapons, with the inherent huge levels of radioactive pollution and their attendant risk of retaliation in kind. == Effectiveness ==