Little Boy | |
---|---|
A post-war "Little Boy" model. | |
Type | Nuclear weapon |
Place of origin | United States |
Specifications | |
Weight | 8,818.49 lbs. 4,000 kg |
Length | 9.84 ft. 3.0 m |
Diameter | 2.3 ft. 0.7 m |
| |
Blast yield | 13 to 18 kilotons |
Little Boy was the codename of the atomic bomb , developed via the "Manhattan Project" which was dropped on Hiroshima, on August 6, 1945 by the B-29 Superfortress Enola Gay, piloted by Colonel Paul Tibbets in the 393d Bombardment Squadron, Heavy of the United States Army Air Forces.[1] It was the first atomic bomb ever used as a weapon, and was dropped three days before the "Fat Man" bomb was used against Nagasaki.[2]
The weapon was developed by the Manhattan Project during World War II. It derived its explosive power from the nuclear fission of uranium 235. The Hiroshima bombing was the second artificial nuclear explosion in history (the first was the "Trinity" test), and it was the first uranium-based detonation. Approximately 600 milligrams of mass were converted into energy. It exploded with a destructive power equivalent to between 13 and 18 kilotons of TNT (estimates vary) and killed approximately 140,000 people. It was also never tested at the Trinity test site (unlike Fat Man), due to the fact that uranium was very rare at the time, and the US didn't want to waste uranium.
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[edit] Basic weapon design
The Mk I "Little Boy" was 10 feet (3.0 m) in length, 28 inches (71 cm) in diameter and weighed 8,900 lb (4 000 kg). The design used the gun method to explosively force a hollow sub-critical mass of uranium-235 and a solid target spike together into a super-critical mass, initiating a nuclear chain reaction. This was accomplished by shooting one piece of the uranium onto the other by means of chemical explosives. It contained 64 kg of uranium, of which 0.7 kg underwent nuclear fission, and of this mass only 0.6 g was transformed into energy.
No full test of a gun-type nuclear weapon had occurred before the "Little Boy" device was dropped over Hiroshima. The only test explosion of a nuclear weapon had been of an implosion-type weapon using plutonium as its fissionable material, on July 16, 1945 at the Trinity test. There were several reasons for not testing the "Little Boy" device. Primarily, scarcity of uranium-235 compared with the relatively large amount of plutonium which, it was expected, could be produced by the Hanford reactors. Additionally, the weapon design was simple enough that it was only deemed necessary to do laboratory tests with the gun-type assembly (known during the war as "tickling the dragon's tail"). Unlike the implosion design, which required sophisticated coordination of shaped explosive charges, the gun-type design was considered almost certain to work.
Although occasionally used in later experimental devices, the design was only used once as a weapon because of the danger of accidental detonation. Little Boy's design was unsafe when compared to modern nuclear weapons, which incorporate safety features to endure various accident scenarios. The main objective of Little Boy was to create a weapon that was absolutely guaranteed to work. As a result, Little Boy incorporated only basic safety mechanisms, so an accidental detonation could easily occur during one or more of the following scenarios:
- a crash could drive the "bullet" onto the "target" resulting in a massive release of radiation, or possibly nuclear detonation.
- an electrical short circuit of some sort.
- the danger of misfire was greater over water. If the force of a crash did not trigger the bomb, water leakage into the system could short it out, possibly leading to detonation. The British Red Beard nuclear weapon also suffered from this design flaw.
- Fire.
- Lightning strike.
None of the other five Mark I bombs built on the model of Little Boy was used by the U.S. Army.
[edit] Assembly details
The exact specifications of the "Little Boy" bomb remain classified because they could still be used to create a viable nuclear weapon. Even so, many sources have speculated as to the design, relying on limited photographic evidence, interviews with former Manhattan Project personnel, and piecing together information from declassified sources to reconstruct its internal dimensions.
According to the website Nuclear Weapon Archive,[3][4] inside the weapon, the uranium-235 material was divided into two parts, following the gun principle: the "projectile" and the "target". The projectile was a hollow cylinder with 60% of the total mass (38.5 kg). It consisted of a stack of 9 uranium rings, each 6.25 inches (159 mm) in diameter with a 4-inch-diameter hole in the center, pressed together into a thin-walled canister 7 inches (180 mm) long. At detonation, it was pushed down a short smooth-bore gun barrel by a tungsten carbide and steel plug. The target was a 4-inch-diameter solid spike, 7 inches long, with 40% of the total mass (25.6 kg). Composed of a stack of 6 washer-like uranium rings somewhat thicker than the projectile rings, it was secured by a 1-inch-diameter bolt through the rings, that protruded out the front of the bomb casing.
When the projectile and plug reached the target, the assembled super-critical mass of uranium would be completely surrounded by a tamper and neutron reflector of tungsten carbide and steel. Neutron generators at the base of the spike would be activated by the impact.
The projectile rings were delivered to Tinian Island on July 26, 1945, by the USS Indianapolis. The target rings arrived two days later by air.
[edit] Counter-intuitive design
For the first fifty years after 1945, every published description and drawing of the Little Boy mechanism assumed that a small, solid projectile was fired into the center of a larger target.[4]
Critical mass considerations dictated that in Little Boy the larger, hollow piece would be the projectile. For the assembled fissile core to have more than two critical masses of U-235, one of the two pieces would need to have more than one critical mass, and to avoid criticality by means of shape. A hole in the center increased the surface area, allowing more fission neutrons to escape and not cause more fission.
It was also important for the larger piece to have minimal contact with the neutron-reflecting tungsten carbide tamper until detonation. As the projectile, only its back end would be in contact with tungsten carbide (see drawing above). The rest of the tungsten carbide surrounded the target spike (called the "insert" by designers) with air space between it and the insert. This packs the maximum amount of fissile material into a gun-assembly design.[5]
[edit] Physical effects of the bomb
Hiroshima was spared conventional bombing to serve as a pristine target, where the effects of a nuclear bomb on an undamaged city could be observed.[6] While damage could be studied later, the energy yield of the untested Little Boy design could be determined only at the moment of detonation, using instruments dropped by parachute from a plane flying in formation with the one that dropped the bomb. Radio-transmitted data from these instruments indicated a yield of about 12 kilotons.
Comparing this yield to the observed damage produced a rule of thumb called the 5 psi lethal area rule. The number of prompt fatalities will approximately equal the number of people inside the lethal area.
The damage came from three main effects: blast, fire, and radiation.[7]
[edit] Blast
The blast from a nuclear bomb is the result of X-ray-heated air (the fireball) sending a shock/pressure wave in all directions at the speed of sound, analogous to thunder generated by lightning. Studies of Little Boy at Hiroshima provided most of the knowledge about nuclear weapon urban blast destruction. Nagasaki was less useful in that respect, since hilly terrain deflected the blast and generated a more complicated pattern of destruction.
At Hiroshima, severe structural damage to buildings extended about 1 mile (1.6 km) from ground zero, making a circle of destruction 2 miles (3.2 km) in diameter. There was little or no structural damage outside of this circle. At one mile, the force of the blast wave was 5 psi, with enough duration to implode houses and reduce them to kindling.
Later test explosions of nuclear weapons with houses and other test structures nearby confirmed that 5 psi (34,000 Pa) is an important threshold. Ordinary urban buildings experiencing it will be crushed, toppled, or gutted by the force of air pressure. The picture at right shows the effects of a nuclear-bomb-generated 5 psi pressure wave on a test structure in Nevada in 1953.
The most important effect of this kind of structural damage was that it created fuel for a firestorm. For this reason, the 5 psi contour defines the lethal area for blast and fire.
[edit] Fire
The first effect of a nuclear explosion is blinding light, accompanied by radiant heat from the fireball. (The Hiroshima fireball was 1,200 feet (370 m) in diameter.) Near ground zero, everything inflammable burst into flame, glass products and sand melted into molten glass, and any humans were instantly vaporized. One famous, anonymous Hiroshima victim left only a shadow, permanently etched into stone steps near a bank building.[8]
Some of the fires started by the fireball's heat were probably blown out by the blast wave. The blast wave would have started additional fires through overturned stoves, wrecked vehicles, electrical shorts, etc. These numerous small fires merged into a single firestorm which consumed everything inside the 5 psi lethal area.
The Hiroshima firestorm was thus two miles (3 km) in diameter, corresponding closely to the severe blast damage zone. (See the USSBS[9] map, right.) Blast-damaged buildings provided fuel for the fire. Structural lumber and furniture were splintered and scattered about. Debris-choked roads obstructed fire fighters. Broken gas pipes fueled the fire, and broken water pipes rendered hydrants useless.
As the map shows, the firestorm jumped natural firebreaks (river channels), as well as prepared firebreaks. The spread of fire stopped only when it reached the edge of the blast-damaged area, encountering less available fuel.
Accurate casualty figures are impossible to determine, because many victims were cremated by the firestorm. For the same reason, the portion of firestorm victims who survived the blast and died of fire can never be known. Casualty figures are based on population estimates inside the lethal area when the bomb detonated.
[edit] Radiation
Local fallout is dust and ash from a bomb crater, contaminated with radioactive fission products. It falls to earth downwind of the crater and can produce, with radiation alone, a lethal area much larger than that from blast and fire. With an air burst, the fission products rise into the stratosphere, where they dissipate and become part of the global environment. Because Little Boy was an air burst 1,900 feet (580 m) above the ground, there was no bomb crater and no local radioactive fallout.[10]
However, intense neutron and gamma radiation came directly from the fireball. Most people close enough to receive lethal doses of direct radiation died in the firestorm before their radiation injuries would have become apparent. Survivors on the edge of the lethal area and beyond suffered injuries from radiation, in addition to those caused by blast and fire.
Some temporary survivors died soon afterward due to acute radiation sickness, but most of the radiation effects are evident only statistically, as increases in cancer rates, birth defects, etc., over the lifetimes of the survivors and their descendants.
[edit] Development of the bomb
The "Little Boy" bomb was constructed through the Manhattan Project during World War II. Because enriched uranium was known to be fissionable, it was the first approach to bomb development pursued. The vast majority of the work in constructing "Little Boy" came in the form of the isotope enrichment of the uranium necessary for the weapon. Enrichment at Oak Ridge, Tennessee began in February 1943, after many years of research.
The development of the first prototypes and the experimental work started in early 1943, at the time when the Los Alamos Design Laboratory became operational in the framework of the Manhattan Project. Originally gun-type designs were pursued for both a uranium and plutonium weapon (the "Thin Man" design), but in April 1944 it was discovered that the spontaneous fission rate for plutonium was too great to use in a gun-type weapon. In July 1944, almost all research at Los Alamos was redirected to the implosion plutonium weapon. In contrast, the uranium bomb was almost trivial to design.
With plutonium found unsuitable for the gun-type design, the team working on the gun weapon (led by A. Francis Birch), faced another problem: the bomb was simple, but they lacked the quantity of uranium-235 necessary for its production. Enough fissile material was not going to be available before mid-1945. Despite this, Birch managed to convince others that this concept was worth pursuing, so that in case of a failure of the plutonium bomb, it would still be possible to use the gun principle. In February 1945, the specifications were completed (model 1850). The bomb, except for the uranium payload, was ready at the beginning of May 1945.
Most of the uranium necessary for the production of the bomb came from the Shinkolobwe mine and was made available thanks to the foresight of the CEO of the High Katanga Mining Union, Edgar Sengier, who had 1000 tons of uranium ore transported to a New York warehouse in 1939. A small amount may have come from a captured German submarine, U-234, after the German surrender in May 1945. The majority of the uranium for Little Boy was enriched in Oak Ridge, Tennessee, primarily by means of electromagnetic separation in calutrons and through gaseous diffusion plants, with a small amount contributed by the cyclotrons at Ernest O. Lawrence's Radiation Laboratory. The core of Little Boy contained 64 kg of uranium, of which 50 kg were enriched to 89%, and the remaining 14 kg at 50%. With enrichment averaging 80%, it could reach about 2.5 critical masses. "Fat Man" and the Trinity "gadget", by way of comparison, had five critical masses.
[edit] Construction and delivery
On July 14, 1945 a train left Los Alamos carrying several "bomb units" (the major non-nuclear parts of a gun-type bomb) together with a single completed uranium projectile; the uranium target was still incomplete. The consignment was delivered to the San Francisco Naval Shipyard at Hunters Point in San Francisco, California[3]. There, two hours before the successful test of Little Boy's plutonium-implosion brother at the Trinity test in New Mexico, the bomb units and the projectile were loaded aboard the heavy cruiser USS Indianapolis. Indianapolis steamed at record speed to the airbase at Tinian island in the Mariana Islands, delivering them ten days later on the 26th. While returning from this mission Indianapolis was sunk by a Japanese submarine, with great loss of life due to delayed rescue. Also on the 26th the three sections of the uranium target assembly were shipped from Kirtland Air Force Base[3] near Albuquerque, New Mexico in three C-54 Skymaster aircraft operated by the 509th Composite Group's Green Hornet squadron[11] [12]. With all the necessary components delivered to Tinian, bomb unit L11 was chosen, and the final Little Boy weapon was assembled and ready by August 1[3].
Handling the completed Little Boy was particularly dangerous. Once cordite was loaded in the breech, any firing of the explosive would at worst cause a nuclear chain reaction and at best a contamination of the explosion zone. The mere contact of the two uranium masses could have caused an explosion with dire consequences, from a simple "fizzle" explosion to an explosion large enough to destroy Tinian (including the 500 B-29s based there, and their supporting infrastructure and personnel). Water was also a risk, since it could serve as a moderator between the fissile materials and cause a violent dispersal of the nuclear material. The uranium projectile could only be inserted with an apparatus that produced a force of 300,000 newtons (67,000 lbf, over 30 tons). For safety reasons, the weaponeer, Captain William Sterling Parsons, decided to load the bags of cordite only after take-off.
[edit] Fuze system
The bomb employed a fuzing system that was designed to detonate at the most destructive altitude.[citation needed] Calculations showed that for the largest destructive effect, the bomb should explode at an altitude of 580 meters (1,900 feet).[citation needed] The resultant fuze design was a three-stage interlock system:[13]
- A timer ensured that the bomb would not explode until at least fifteen seconds after release, one-quarter of the predicted fall time, to ensure safety of the aircraft. The timer was activated when the electrical pullout plugs connecting it to the airplane were pulled loose as the bomb fell, switching it to internal (24V battery) power and starting the timer. At the end of the 15 seconds the batteries then powered the radar system and passed responsibility to the barometric stage.[14]
- The purpose of the barometric stage was to delay activating the radar altimeter firing command circuit until near detonation altitude. A thin metallic membrane was gradually deformed as ambient air pressure increased during descent.[citation needed] The barometric fuze was not considered accurate enough to detonate the bomb at the precise ignition height, because air pressure varies with local conditions.[citation needed] When the bomb reached the design height for this stage (reportedly 2,000 meters) the membrane closed a circuit, activating the circuit between the radar altimeter and the projectile gun.[citation needed] The barometric stage was added because of a worry that external radar signals might detonate the bomb too early.[15]
- The doubly-redundant radar system employed four radar altimeters[16] that independently detected altitude by radar reflections from the ground. When any two of the four altimeters sensed the correct height, the firing switch closed, igniting the cordite charge.[citation needed] This launched the uranium projectile towards the opposite end of the gun barrel at an eventual muzzle velocity of 1000 feet per second (300 meters per second).[citation needed] Approximately 10 milliseconds later the chain reaction occurred, lasting less than 1 μs.[citation needed] The radar altimeters used were modified U.S. Army Air Corps APS-13 fighter tail warning radars, nicknamed "Archie", originally designed to warn a pilot of another plane approaching from behind.[17]
[edit] The bombing of Hiroshima
The bomb was armed in flight 31,000ft (9600m) above the city, then dropped at approximately 8:15 a.m. (JST). The detonation happened at an altitude of 1980ft (580m). With a power of 13 to 16 kilotons, it was less powerful than "Fat Man," which was dropped on Nagasaki (21–23 kt). The official yield estimate of "Little Boy" was about 15 kilotons of TNT equivalent in explosive force, i.e. 6.3 × 1013 joules = 63 TJ (terajoules).[18] However, the damage and the number of victims at Hiroshima were much higher, as Hiroshima was on flat terrain, while the hypocenter of Nagasaki lay in a small valley.
According to published US Army figures 66,000 people were killed as a direct result of the Hiroshima blast, and 69,000 were injured to varying degrees.
The U.S. Department of Energy gives this account of the death toll of the bombing of Hiroshima:
"By the end of 1945, because of the lingering effects of radioactive fallout and other after effects, the Hiroshima death toll was probably over 100,000. The five-year death total may have reached or even exceeded 200,000, as cancer and other long-term effects took hold."[19]
The success of the bombing was reported with great enthusiasm in the United States in the days following the attacks. See Atomic bombings of Hiroshima and Nagasaki for discussion of contemporary opposition to the bombings, on both moral and military grounds.
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