Documentation and Diagrams of the Atomic Bomb

 

Documentation and Diagrams of the Atomic Bomb

File courtesy of Outlaw Labs
Author: J.D. Dyson [jdyson@nyx.net]


DISCLAIMER

The information contained in this file is strictly for academic use aloneUC Berkeley will bear no responsibility for any use otherwiseIt would be wise to note that the personnel who design and construct these devices are skilled physicists and are more knowledgeable in these matters than any layperson can ever hope to be... Should a layperson attempt to build a device such as this, chances are s/he would probably kill his/herself not by a nuclear detonation, but rather through radiation exposureWe here at UC Berkeley do not recommend using this file beyond the realm of casual or academic curiosity.


Table of Contents

I. The History of the Atomic Bomb

A. Development (The Manhattan Project)
B. Detonation

1. Hiroshima
2Nagasaki
3Byproducts of atomic detonations
4Blast Zones

II. Nuclear Fission/Nuclear Fusion

A. Fission (A-Bomb) & Fusion (H-Bomb)
B. U-235, U-238 and Plutonium

III. The Mechanism of The Bomb

A. Altimeter
B. Air Pressure Detonator
C. Detonating Head(s)
D. Explosive Charge(s)
E. Neutron Deflector
F. Uranium & Plutonium
G. Lead Shield
H. Fuses

IV. The Diagram of The Bomb

A. The Uranium Bomb
BThe Plutonium Bomb


I. The History of the Atomic Bomb

On August 2nd 1939, just before the beginning of World War II, Albert Einstein wrote to then President Franklin D. RooseveltEinstein and several other scientists told Roosevelt of efforts in Nazi Germany to purify U-235 with which might in turn be used to build an atomic bombIt was shortly thereafter that the United States Government began the serious undertaking known only then as the Manhattan ProjectSimply put, the Manhattan Project was committed to expedient research and production that would produce a viable atomic bomb.

The most complicated issue to be addressed was the production of ample amounts of `enriched' uranium to sustain a chain reactionAt the time, Uranium-235 was very hard to extractIn fact, the ratio of conversion from Uranium ore to Uranium metal is 500:1An additional drawback is that the 1 part of Uranium that is finally refined from the ore consists of over 99% Uranium-238, which is practically useless for an atomic bombTo make it even more difficult, U-235 and U-238 are precisely similar in their chemical makeupThis proved to be as much of a challenge as separating a solution of sucrose from a solution of glucoseNo ordinary chemical extraction could separate the two isotopesOnly mechanical methods could effectively separate U-235 from U-238Several scientists at Columbia University managed to solve this dilemma.

A massive enrichment laboratory/plant was constructed at Oak RidgeTennesseeH.C. Urey, along with his associates and colleagues at Columbia University, devised a system that worked on the principle of gaseous diffusionFollowing this process, Ernest O. Lawrence (inventor of the Cyclotron) at the University of California in Berkeley implemented a process involving magnetic separation of the two isotopes.

Following the first two processes, a gas centrifuge was used to further separate the lighter U-235 from the heavier non-fissionable U-238 by their massOnce all of these procedures had been completed, all that needed to be done was to put to the test the entire concept behind atomic fission[For more information on these procedures of refining Uranium, see Section 3.]

Over the course of six years, ranging from 1939 to 1945, more than 2 billion dollars were spent on the Manhattan ProjectThe formulas for refining Uranium and putting together a working bomb were created and seen to their logical ends by some of the greatest minds of our timeAmong these people who unleashed the power of the atomic bomb was J. Robert Oppenheimer.

Oppenheimer was the major force behind the Manhattan ProjectHe literally ran the show and saw to it that all of the great minds working on this project made their brainstorms workHe oversaw the entire project from its conception to its completion.

Finally the day came when all at Los Alamos would find out whether or not The Gadget (code-named as such during its development) was either going to be the colossal dud of the century or perhaps end the warIt all came down to a fateful morning of midsummer, 1945.

At 5:29:45 (Mountain War Time) on July 16th, 1945, in a white blaze that stretched from the basin of the Jemez Mountains in northern New Mexico to the still-dark skies, The Gadget ushered in the Atomic AgeThe light of the explosion then turned orange as the atomic fireball began shooting upwards at 360 feet per second, reddening and pulsing as it cooledThe characteristic mushroom cloud of radioactive vapor materialized at 30,000 feetBeneath the cloud, all that remained of the soil at the blast site were fragments of jade green radioactive glass. ...All of this caused by the heat of the reaction.

The brilliant light from the detonation pierced the early morning skies with such intensity that residents from a faraway neighboring community would swear that the sun came up twice that dayEven more astonishing is that a blind girl saw the flash 120 miles away.

Upon witnessing the explosion, reactions among the people who created it were mixedIsidor Rabi felt that the equilibrium in nature had been upset -- as if humankind had become a threat to the world it inhabitedJ. Robert Oppenheimer, though ecstatic about the success of the project, quoted a remembered fragment from Bhagavad Gita"I am become Death," he said, "the destroyer of worlds.Ken Bainbridge, the test director, told Oppenheimer, "Now we're all sons of bitches."

Several participants, shortly after viewing the results, signed petitions against loosing the monster they had created, but their protests fell on deaf earsAs it later turned out, the Jornada del Muerto of New Mexico was not the last site on planet Earth to experience an atomic explosion.

As many know, atomic bombs have been used only twice in warfareThe first and foremost blast site of the atomic bomb is HiroshimaA Uranium bomb (which weighed in at over 4 & 1/2 tons) nicknamed "Little Boy" was dropped on Hiroshima August 6th, 1945The Aioi Bridge, one of 81 bridges connecting the seven-branched delta of the Ota River, was the aiming point of the bombGround Zero was set at 1,980 feetAt 0815 hours, the bomb was dropped from the Enola GayIt missed by only 800 feetAt 0816 hours, in the flash of an instant, 66,000 people were killed and 69,000 people were injured by a 10 kiloton atomic explosion.

The point of total vaporization from the blast measured one half of a mile in diameterTotal destruction ranged at one mile in diameterSevere blast damage carried as far as two miles in diameterAt two and a half miles, everything flammable in the area burnedThe remaining area of the blast zone was riddled with serious blazes that stretched out to the final edge at a little over three miles in diameter[See diagram below for blast ranges from the atomic blast.]

On August 9th 1945, Nagasaki fell to the same treatment as HiroshimaOnly this time, a Plutonium bomb nicknamed "Fat Man" was dropped on the cityEven though the "Fat Man" missed by over a mile and a half, it still leveled nearly half the cityNagasaki's population dropped in one split-second from 422,000 to 383,00039,000 were killed, over 25,000 were injuredThat blast was less than 10 kilotons as wellEstimates from physicists who have studied each atomic explosion state that the bombs that were used had utilized only 1/10th of 1 percent of their respective explosive capabilities.

While the mere explosion from an atomic bomb is deadly enough, its destructive ability doesn't stop thereAtomic fallout creates another hazard as wellThe rain that follows any atomic detonation is laden with radioactive particlesMany survivors of the Hiroshima and Nagasaki blasts succumbed to radiation poisoning due to this occurance.

The atomic detonation also has the hidden lethal surprise of affecting the future generations of those who live through itLeukemia is among the greatest of afflictions that are passed on to the offspring of survivors.

While the main purpose behind the atomic bomb is obvious, there are many by-products that have been brought into consideration in the use of all weapons atomicWith one small atomic bomb, a massive area's communications, travel and machinery will grind to a dead halt due to the EMP (Electro- Magnetic Pulse) that is radiated from a high-altitude atomic detonationThese high-level detonations are hardly lethal, yet they deliver a serious enough EMP to scramble any and all things electronic ranging from copper wires all the way up to a computer's CPU within a 50 mile radius.

At one time, during the early days of The Atomic Age, it was a popular notion that one day atomic bombs would one day be used in mining operations and perhaps aid in the construction of another Panama CanalNeedless to say, it never came aboutInstead, the military applications of atomic destruction increasedAtomic tests off of the Bikini Atoll and several other sites were common up until the Nuclear Test Ban Treaty was introducedPhotos of nuclear test sites here in the United States can be obtained through the Freedom of Information Act.

Breakdown of the Atomic Bomb's Blast Zones

 
 
                                       .
                         .                           .
 
 
              .                        .                        .
                             .                   .
               [5]                    [4]                    [5]
                                       .
                      .        .               .        .
 
       .                  .                         .                  .
 
                 .          [3]        _        [3]          .
                      .           .   [2]   .           .
                                .     _._     .
                               .    .~   ~.    .
    .          . [4] .         .[2].  [1]  .[2].         . [4] .          .
                               .    .     .    .
                                .    ~-.-~    .
                      .           .   [2]   .           .
                 .          [3]        -        [3]          .
 
       .                  .                         .                  .
 
                      .        ~               ~        .
                                       ~
               [5]           .        [4]        .           [5]
                                       .
              .                                                 .
 
 
                         .                           .
                                       .
 

Diagram Outline

 
     [1]  Vaporization Point
          ------------------
          Everything is vaporized by the atomic blast.  98% fatalities.
          Overpress=25 psi.  Wind velocity=320 mph.
 
     [2]  Total Destruction
          -----------------
          All structures above ground are destroyed90% fatalities.
          Overpress=17 psi.  Wind velocity=290 mph.
 
     [3]  Severe Blast Damage
          -------------------
          Factories and other large-scale building collapse.  Severe damage
          to highway bridges.  Rivers sometimes flow countercurrent.
          65% fatalities, 30% injured.
          Overpress=9 psi.  Wind velocity=260 mph.
 
     [4]  Severe Heat Damage
          ------------------
          Everything flammable burns.  People in the area suffocate due to
          the fact that most available oxygen is consumed by the fires.
          50% fatalities, 45% injured.
          Overpress=6 psi.  Wind velocity=140 mph.
 
     [5]  Severe Fire & Wind Damage
          -------------------------
          Residency structures are severely damaged.  People are blown
          around2nd and 3rd-degree burns suffered by most survivors.
          15% dead.  50% injured.
          Overpress=3 psi.  Wind velocity=98 mph.

Blast Zone Radii

[3 different bomb types]

 
  ______________________   ______________________   ______________________
 |                      | |                      | |                      |
 |    -[10 KILOTONS]-   | |     -[1 MEGATON]-    | |    -[20 MEGATONS]-   |
 |----------------------| |----------------------| |----------------------|
 | Airburst - 1,980 ft  | | Airburst - 8,000 ft  | | Airburst - 17,500 ft |
 |______________________| |______________________| |______________________|
 |                      | |                      | |                      |
 |  [1]  0.5 miles      | |  [1]  2.5 miles      | |  [1]  8.75 miles     |
 |  [2]  1 mile         | |  [2]  3.75 miles     | |  [2]  14 miles       |
 |  [3]  1.75 miles     | |  [3]  6.5 miles      | |  [3]  27 miles       |
 |  [4]  2.5 miles      | |  [4]  7.75 miles     | |  [4]  31 miles       |
 |  [5]  3 miles        | |  [5]  10 miles       | |  [5]  35 miles       |
 |                      | |                      | |                      |
 |______________________| |______________________| |______________________|

II. Nuclear Fission/Nuclear Fusion

There are 2 types of atomic explosions that can be facilitated by U-235; fission and fusionFission, simply put, is a nuclear reaction in which an atomic nucleus splits into fragments, usually two fragments of comparable mass, with the evolution of approximately 100 million to several hundred million volts of energyThis energy is expelled explosively and violently in the atomic bombA fusion reaction is invariably started with a fission reaction, but unlike the fission reaction, the fusion (Hydrogen) bomb derives its power from the fusing of nuclei of various hydrogen isotopes in the formation of helium nucleiBeing that the bomb in this file is strictly atomic, the other aspects of the Hydrogen Bomb will be set aside for now.

The massive power behind the reaction in an atomic bomb arises from the forces that hold the atom togetherThese forces are akin to, but not quite the same as, magnetism.

Atoms are comprised of three sub-atomic particlesProtons and neutrons cluster together to form the nucleus (central mass) of the atom while the electrons orbit the nucleus much like planets around a sun. It is these particles that determine the stability of the atom.

Most natural elements have very stable atoms which are impossible to split except by bombardment by particle acceleratorsFor all practical purposes, the one true element whose atoms can be split comparatively easily is the metal UraniumUranium's atoms are unusually large, henceforth, it is hard for them to hold together firmlyThis makes Uranium-235 an exceptional candidate for nuclear fission.

Uranium is a heavy metal, heavier than gold, and not only does it have the largest atoms of any natural element, the atoms that comprise Uranium have far more neutrons than protonsThis does not enhance their capacity to split, but it does have an important bearing on their capacity to facilitate an explosion.

There are two isotopes of UraniumNatural Uranium consists mostly of isotope U-238, which has 92 protons and 146 neutrons (92+146=238)Mixed with this isotope, one will find a 0.6% accumulation of U-235, which has only 143 neutronsThis isotope, unlike U-238, has atoms that can be split, thus it is termed "fissionable" and useful in making atomic bombsBeing that U-238 is neutron-heavy, it reflects neutrons, rather than absorbing them like its brother isotope, U-235(U-238 serves no function in an atomic reaction, but its properties provide an excellent shield for the U-235 in a constructed bomb as a neutron reflectorThis helps prevent an accidental chain reaction between the larger U-235 mass and its `bullet' counterpart within the bombAlso note that while U-238 cannot facilitate a chain-reaction, it can be neutron-saturated to produce Plutonium (Pu-239)Plutonium is fissionable and can be used in place of Uranium-235 {albeit, with a different model of detonator} in an atomic bomb[See Sections 3 & 4 of this file.])

Both isotopes of Uranium are naturally radioactiveTheir bulky atoms disintegrate over a period of timeGiven enough time, (over 100,000 years or more) Uranium will eventually lose so many particles that it will turn into the metal leadHowever, this process can be acceleratedThis process is known as the chain reactionInstead of disintegrating slowly, the atoms are forcibly split by neutrons forcing their way into the nucleusA U-235 atom is so unstable that a blow from a single neutron is enough to split it and henceforth bring on a chain reactionThis can happen even when a critical mass is present. When this chain reaction occurs, the Uranium atom splits into two smaller atoms of different elements, such as Barium and Krypton.

When a U-235 atom splits, it gives off energy in the form of heat and Gamma radiation, which is the most powerful form of radioactivity and the most lethalWhen this reaction occurs, the split atom will also give off two or three of its `spare' neutrons, which are not needed to make either Barium or KryptonThese spare neutrons fly out with sufficient force to split other atoms they come in contact with[See chart belowIn theory, it is necessary to split only one U-235 atom, and the neutrons from this will split other atoms, which will split more...so on and so forthThis progression does not take place arithmetically, but geometricallyAll of this will happen within a millionth of a second.

The minimum amount to start a chain reaction as described above is known as SuperCritical Mass. The actual mass needed to facilitate this chain reaction depends upon the purity of the material, but for pure U-235, it is 110 pounds (50 kilograms), but no Uranium is never quite pure, so in reality more will be needed.

Uranium is not the only material used for making atomic bombsAnother material is the element Plutonium, in its isotope Pu-239Plutonium is not found naturally (except in minute traces) and is always made from UraniumThe only way to produce Plutonium from Uranium is to process U-238 through a nuclear reactorAfter a period of time, the intense radioactivity causes the metal to pick up extra particles, so that more and more of its atoms turn into Plutonium.

Plutonium will not start a fast chain reaction by itself, but this difficulty is overcome by having a neutron source, a highly radioactive material that gives off neutrons faster than the Plutonium itselfIn certain types of bombs, a mixture of the elements Beryllium and Polonium is used to bring about this reactionOnly a small piece is neededThe material is not fissionable in and of itself, but merely acts as a catalyst to the greater reaction.

Diagram of a Chain Reaction

 
                                       |
                                       |
                                       |
                                       |
    [1]------------------------------> o
 
                                    . o o .
                                   . o_0_o . <-----------------------[2]
                                   . o 0 o .
                                    . o o .
 
                                       |
                                      \|/
                                       ~
 
                                 . o o. .o o .
    [3]-----------------------> . o_0_o"o_0_o .
                                . o 0 o~o 0 o .
                                 . o o.".o o .
                                       |
                                  /    |    \
                                |/_    |    _\|
                                ~~     |     ~~
                                       |
                           o o         |        o o
    [4]-----------------> o_0_o        |       o_0_o <---------------[5]
                          o~0~o        |       o~0~o
                           o o )       |      ( o o
                              /        o       \
                             /        [1]       \
                            /                    \
                           /                      \
                          /                        \
                         o [1]                  [1] o
                 . o o .            . o o .            . o o .
                . o_0_o .          . o_0_o .          . o_0_o .
                . o 0 o .  <-[2]-> . o 0 o . <-[2]->  . o 0 o .
                 . o o .            . o o .            . o o .
 
                  /                    |                    \
                |/_                   \|/                   _\|
                ~~                     ~                     ~~
 
      . o o. .o o .              . o o. .o o .              . o o. .o o .
     . o_0_o"o_0_o .            . o_0_o"o_0_o .            . o_0_o"o_0_o .
     . o 0 o~o 0 o . <--[3]-->  . o 0 o~o 0 o .  <--[3]--> . o 0 o~o 0 o .
      . o o.".o o .              . o o.".o o .              . o o.".o o .
        .   |   .                  .   |   .                  .   |   .
       /    |    \                /    |    \                /    |    \
       :    |    :                :    |    :                :    |    :
       :    |    :                :    |    :                :    |    :
      \:/   |   \:/              \:/   |   \:/              \:/   |   \:/
       ~    |    ~                ~    |    ~                ~    |    ~
  [4] o o   |   o o [5]      [4] o o   |   o o [5]      [4] o o   |   o o [5]
     o_0_o  |  o_0_o            o_0_o  |  o_0_o            o_0_o  |  o_0_o
     o~0~o  |  o~0~o            o~0~o  |  o~0~o            o~0~o  |  o~0~o
      o o ) | ( o o              o o ) | ( o o              o o ) | ( o o
         /  |  \                    /  |  \                    /  |  \
        /   |   \                  /   |   \                  /   |   \
       /    |    \                /    |    \                /    |    \
      /     |     \              /     |     \              /     |     \
     /      o      \            /      o      \            /      o      \
    /      [1]      \          /      [1]      \          /      [1]      \
   o                 o        o                 o        o                 o
  [1]               [1]      [1]               [1]      [1]               [1]

Diagram Outline

 
                        [1] - Incoming Neutron
                        [2] - Uranium-235
                        [3] - Uranium-236
                        [4] - Barium Atom
                        [5] - Krypton Atom

III. The Mechanism of The Bomb

Altimeter

An ordinary aircraft altimeter uses a type of Aneroid Barometer which measures the changes in air pressure at different heightsHowever, changes in air pressure due to the weather can adversely affect the altimeter's readingsIt is far more favorable to use a radar (or radio) altimeter for enhanced accuracy when the bomb reaches Ground Zero.

While Frequency Modulated-Continuous Wave (FM CW) is more complicated, the accuracy of it far surpasses any other type of altimeterLike simple pulse systems, signals are emitted from a radar aerial (the bomb), bounced off the ground and received back at the bomb's altimeterThis pulse system applies to the more advanced altimeter system, only the signal is continuous and centered around a high frequency such as 4200 MHzThis signal is arranged to steadily increase at 200 MHz per interval before dropping back to its original frequency.

As the descent of the bomb begins, the altimeter transmitter will send out a pulse starting at 4200 MHzBy the time that pulse has returned, the altimeter transmitter will be emitting a higher frequencyThe difference depends on how long the pulse has taken to do the return journeyWhen these two frequencies are mixed electronically, a new frequency (the difference between the two) emergesThe value of this new frequency is measured by the built-in microchipsThis value is directly proportional to the distance travelled by the original pulse, so it can be used to give the actual height.

In practice, a typical FM CW radar today would sweep 120 times per secondIts range would be up to 10,000 feet (3000 m) over land and 20,000 feet (6000 m) over sea, since sound reflections from water surfaces are clearer.

The accuracy of these altimeters is within 5 feet (1.5 m) for the higher rangesBeing that the ideal airburst for the atomic bomb is usually set for 1,980 feet, this error factor is not of enormous concern.

The high cost of these radar-type altimeters has prevented their use in commercial applications, but the decreasing cost of electronic components should make them competitive with barometric types before too long.

Air Pressure Detonator

The air pressure detonator can be a very complex mechanism, but for all practical purposes, a simpler model can be usedAt high altitudes, the air is of lesser pressureAs the altitude drops, the air pressure increasesA simple piece of very thin magnetized metal can be used as an air pressure detonatorAll that is needed is for the strip of metal to have a bubble of extremely thin metal forged in the center and have it placed directly underneath the electrical contact which will trigger the conventional explosive detonationBefore setting the strip in place, push the bubble in so that it will be inverted.

Once the air pressure has achieved the desired level, the magnetic bubble will snap back into its original position and strike the contact, thus completing the circuit and setting off the explosive(s).

Detonating Head

The detonating head (or heads, depending on whether a Uranium or Plutonium bomb is being used as a model) that is seated in the conventional explosive charge(s) is similar to the standard-issue blasting capIt merely serves as a catalyst to bring about a greater explosionCalibration of this device is essentialToo small of a detonating head will only cause a colossal dud that will be doubly dangerous since someone's got to disarm and re-fit the bomb with another detonating head(an added measure of discomfort comes from the knowledge that the conventional explosive may have detonated with insufficient force to weld the radioactive metalsThis will cause a supercritical mass that could go off at any time.The detonating head will receive an electric charge from the either the air pressure detonator or the radar altimeter's coordinating detonator, depending on what type of system is usedThe Du Pont company makes rather excellent blasting caps that can be easily modified to suit the required specifications.

Conventional Explosive Charge(s)

This explosive is used to introduce (and weld) the lesser amount of Uranium to the greater amount within the bomb's housing[The amount of pressure needed to bring this about is unknown and possibly classified by the United States Government for reasons of National Security]

Plastic explosives work best in this situation since they can be manipulated to enable both a Uranium bomb and a Plutonium bomb to detonateOne very good explosive is Urea NitrateThe directions on how to make Urea Nitrate are as follows:

Ingredients

  1. 1 cup concentrated solution of uric acid (C5 H4 N4 O3)
  2. 1/3 cup of nitric acid
  3. 4 heat-resistant glass containers
  4. 4 filters (coffee filters will do)

Filter the concentrated solution of uric acid through a filter to remove impuritiesSlowly add 1/3 cup of nitric acid to the solution and let the mixture stand for 1 hourFilter again as beforeThis time the Urea Nitrate crystals will collect on the filterWash the crystals by pouring water over them while they are in the filterRemove the crystals from the filter and allow 16 hours for them to dryThis explosive will need a blasting cap to detonate.

It may be necessary to make a quantity larger than the aforementioned list calls for to bring about an explosion great enough to cause the Uranium (or Plutonium) sections to weld together on impact.

Neutron Deflector

The neutron deflector is comprised solely of Uranium-238Not only is U-238 non-fissionable, it also has the unique ability to reflect neutrons back to their source.

The U-238 neutron deflector can serve 2 purposesIn a Uranium bomb, the neutron deflector serves as a safeguard to keep an accidental supercritical mass from occurring by bouncing the stray neutrons from the `bullet' counterpart of the Uranium mass away from the greater mass below it (and vice- versa)The neutron deflector in a Plutonium bomb actually helps the wedges of Plutonium retain their neutrons by `reflecting' the stray particles back into the center of the assembly[See diagram in Section 4 of this file.]

Uranium & Plutonium

Uranium-235 is very difficult to extractIn fact, for every 25,000 tons of Uranium ore that is mined from the earth, only 50 tons of Uranium metal can be refined from that, and 99.3% of that metal is U-238 which is too stable to be used as an active agent in an atomic detonationTo make matters even more complicated, no ordinary chemical extraction can separate the two isotopes since both U-235 and U-238 possess precisely identical chemical characteristicsThe only methods that can effectively separate U-235 from U-238 are mechanical methods.

U-235 is slightly, but only slightly, lighter than its counterpart, U-238A system of gaseous diffusion is used to begin the separating process between the two isotopesIn this system, Uranium is combined with fluorine to form Uranium Hexafluoride gasThis mixture is then propelled by low- pressure pumps through a series of extremely fine porous barriersBecause the U-235 atoms are lighter and thus propelled faster than the U-238 atoms, they could penetrate the barriers more rapidlyAs a result, the U-235's concentration became successively greater as it passed through each barrierAfter passing through several thousand barriers, the Uranium Hexafluoride contains a relatively high concentration of U-235 -- 2% pure Uranium in the case of reactor fuel, and if pushed further could (theoretically) yield up to 95% pure Uranium for use in an atomic bomb.

Once the process of gaseous diffusion is finished, the Uranium must be refined once againMagnetic separation of the extract from the previous enriching process is then implemented to further refine the UraniumThis involves electrically charging Uranium Tetrachloride gas and directing it past a weak electromagnetSince the lighter U-235 particles in the gas stream are less affected by the magnetic pull, they can be gradually separated from the flow.

Following the first two procedures, a third enrichment process is then applied to the extract from the second processIn this procedure, a gas centrifuge is brought into action to further separate the lighter U-235 from its heavier counter-isotopeCentrifugal force separates the two isotopes of Uranium by their massOnce all of these procedures have been completed, all that need be done is to place the properly molded components of Uranium-235 inside a warhead that will facilitate an atomic detonation.

Supercritical mass for Uranium-235 is defined as 110 lbs (50 kgs) of pure Uranium.

Depending on the refining process(es) used when purifying the U-235 for use, along with the design of the warhead mechanism and the altitude at which it detonates, the explosive force of the A-bomb can range anywhere from 1 kiloton (which equals 1,000 tons of TNT) to 20 megatons (which equals 20 million tons of TNT -- which, by the way, is the smallest strategic nuclear warhead we possess today{Point in fact -- One Trident Nuclear Submarine carries as much destructive power as 25 World War II's}).

While Uranium is an ideally fissionable material, it is not the only onePlutonium can be used in an atomic bomb as wellBy leaving U-238 inside an atomic reactor for an extended period of time, the U-238 picks up extra particles (neutrons especially) and gradually is transformed into the element Plutonium.

Plutonium is fissionable, but not as easily fissionable as UraniumWhile Uranium can be detonated by a simple 2-part gun-type device, Plutonium must be detonated by a more complex 32-part implosion chamber along with a stronger conventional explosive, a greater striking velocity and a simultaneous triggering mechanism for the conventional explosive packsAlong with all of these requirements comes the additional task of introducing a fine mixture of Beryllium and Polonium to this metal while all of these actions are occurring.

Supercritical mass for Plutonium is defined as 35.2 lbs (16 kgs)This amount needed for a supercritical mass can be reduced to a smaller quantity of 22 lbs (10 kgs) by surrounding the Plutonium with a U-238 casing.

To illustrate the vast difference between a Uranium gun-type detonator and a Plutonium implosion detonator, here is a quick rundown.

Uranium Detonator

Comprised of 2 partsLarger mass is spherical and concaveSmaller mass is precisely the size and shape of the `missing' section of the larger massUpon detonation of conventional explosive, the smaller mass is violently injected and welded to the larger massSupercritical mass is reached, chain reaction follows in one millionth of a second.

Plutonium Detonator

Comprised of 32 individual 45-degree pie-shaped sections of Plutonium surrounding a Beryllium/Polonium mixtureThese 32 sections together form a sphereAll of these sections must have the precisely equal mass (and shape) of the othersThe shape of the detonator resembles a soccerballUpon detonation of conventional explosives, all 32 sections must merge with the B/P mixture within 1 ten-millionths of a second.

Diagram

 
 ____________________________________________________________________________
                                       |
            [Uranium Detonator]        |         [Plutonium Detonator]
 ______________________________________|_____________________________________
                _____                  |
               |    :|                 |               . [2] .
               |    :|                 |           . ~   \_/   ~ .
               | [2]:|                 |        ..        .        ..
               |    :|                 |      [2]|        .        |[2]
               |   .:|                 |     . ~~~ .      .      . ~~~ .
               `...::'                 |    .        .    .    .        .
               _ ~~~ _                 |   .           .  ~  .           .
            . `|     |':..             | [2]\.  .  .  .  [1]  .  .  .  ./[2]
         .     |     | `:::.           |   ./          . ~~~ .          \.
               |     |   `:::          |   .         .    :    .         .
       .       |     |    ::::         |    .      .      .      .      .
               | [1] |    ::|::        |     . ___        .        ___ .
      .        `.   .'   ,::||:        |      [2]|        .        |[2]
                 ~~~     ::|||:        |        .'        _        `.
       ..        [2]   .::|||:'        |           .     / \     .
        ::...       ..::||||:'         |              ~ -[2]- ~
         :::::::::::::||||::'          |
          ``::::||||||||:''            |
              ``:::::''                |
                                       |
                                       |
                                       |
                                       |
       [1] = Collision Point           |      [1] = Collision Point
       [2] - Uranium Section(s)        |      [2] = Plutonium Section(s)
                                       |
 ______________________________________|_____________________________________

Lead Shield

The lead shield's only purpose is to prevent the inherent radioactivity of the bomb's payload from interfering with the other mechanisms of the bombThe neutron flux of the bomb's payload is strong enough to short circuit the internal circuitry and cause an accidental or premature detonation.

Fuses

The fuses are implemented as another safeguard to prevent an accidental detonation of both the conventional explosives and the nuclear payloadThese fuses are set near the surface of the `nose' of the bomb so that they can be installed easily when the bomb is ready to be launchedThe fuses should be installed only shortly before the bomb is launchedTo affix them before it is time could result in an accident of catastrophic proportions.


IV. The Diagram of the Atomic Bomb

Gravity Bomb Model

Cutaway Sections Visible


 
                                      /\
                                     /  \ <---------------------------[1]
                                    /    \
                  _________________/______\_________________
                 | :      ||:      ~      ~               : |
     [2]-------> | :      ||:                             : |
                 | :      ||:                             : |
                 | :      ||:                             : |
                 | :      ||:                             : |
                 | :      ||:                             : |
                 | :      ||:                             : |
                 | :      ||:                             : |
                 | :      ||:                             : |
                 | :      ||:                             : |
                 | :      ||:                             : |
                 | :      ||:                             : |
                 | :______||:_____________________________: |
                 |/_______||/______________________________\|
                  \       ~\       |              |         /
                   \       |\      |              |        /
                    \      | \     |              |       /
                     \     |  \    |              |      /
                      \    |___\   |______________|     /
                       \  |     \ |~               \   /
                        \|_______\|_________________\_/
                        |_____________________________|
                        /                             \
                       /       _________________       \
                      /      _/                 \_      \
                     /    __/                     \__    \
                    /    /                           \    \
                   /__ _/                             \_ __\
     [3]_______________________________                 \ _|
                   / /                 \                 \ \
                  / /                  \/                 \ \
                 / /              ___________              \ \
                | /            __/___________\__            \ |
                | |_  ___     /=================\     ___  _| |
     [4]---------> _||___|====|[[[[[[[|||]]]]]]]|====|___||_ <--------[4]
                | |           |-----------------|           | |
                | |           |o=o=o=o=o=o=o=o=o| <-------------------[5]
                | |            \_______________/            | |
                | |__                |: :|                __| |
                | |  \______________ |: :| ______________/  | |
                | | ________________\|: :|/________________ | |
                | |/            |::::|: :|::::|            \| |
     [6]----------------------> |::::|: :|::::| <---------------------[6]
                | |             |::::|: :|::::|             | |
                | |             |::==|: :|== <------------------------[9]
                | |             |::__\: :/__::|             | |
                | |             |::  ~: :~  ::|             | |
     [7]----------------------------> \_/   ::|             | |
                | |~\________/~\|::    ~    ::|/~\________/~| |
                | |            ||::         <-------------------------[8]
                | |_/~~~~~~~~\_/|::_ _ _ _ _::|\_/~~~~~~~~\_| |
     [9]-------------------------->_=_=_=_=_::|             | |
                | |             :::._______.:::             | |
                | |            .:::|       |:::..           | |
                | |        ..:::::'|       |`:::::..        | |
     [6]---------------->.::::::' ||       || `::::::.<---------------[6]
                | |    .::::::' | ||       || | `::::::.    | |
               /| |  .::::::'   | ||       || |   `::::::.  | |
              | | | .:::::'     | ||    <-----------------------------[10]
              | | |.:::::'      | ||       || |      `:::::.| |
              | | ||::::'       | |`.     .'| |       `::::|| |
    [11]___________________________  ``~''  __________________________[11]
              : | | \::            \       /            ::/ | |
             |  | |  \:_________|_|\/__ __\/|_|_________:/  | |
             /  | |   |  __________~___:___~__________  |   | |
            ||  | |   | |          |:::::::|          | |   | |
    [12]   /|:  | |   | |          |:::::::|          | |   | |
  |~~~~~  / |:  | |   | |          |:::::::|          | |   | |
  |----> / /|:  | |   | |          |:::::::|        <-----------------[10]
  |     / / |:  | |   | |          |:::::::|          | |   | |
  |      /  |:  | |   | |          |::::<-----------------------------[13]
  |     /  /|:  | |   | |          |:::::::|          | |   | |
  |    /  / |:  | |   | |          `:::::::'          | |   | |
  |  _/  / /:~: | |   | `:           ``~''           :' |   | |
  |  |  / / ~.. | |   |: `:                         :' :|   | |
  |->| / /   :  | |   :::  `.                     .' <----------------[11]
  |  |/ / ^   ~\|  \  ::::.  `.                 .'  .::::  /  |
  |  ~   /|\    |   \_::::::.  `.             .'  .::::::_/   |
  |_______|     |      \::::::.  `.         .'  .:::<-----------------[6]
                |_________\:::::.. `~.....~' ..:::::/_________|
                |          \::::::::.......::::::::/          |
                |           ~~~~~~~~~~~~~~~~~~~~~~~           |
                `.                                           .'
                 `.                                         .'
                  `.                                       .'
                   `:.                                   .:'
                    `::.                               .::'
                      `::..                         ..::'
                        `:::..                   ..:::'
                          `::::::...        ..::::::'
    [14]------------------> `:____:::::::::::____:' <-----------------[14]
                              ```::::_____::::'''
                                     ~~~~~
 
                              - Diagram Outline -
                             ---------------------
 
                        [1] - Tail Cone
                        [2] - Stabilizing Tail Fins
                        [3] - Air Pressure Detonator
                        [4] - Air Inlet Tube(s)
                        [5] - Altimeter/Pressure Sensors
                        [6] - Lead Shield Container
                        [7] - Detonating Head
                        [8] - Conventional Explosive Charge
                        [9] - Packing
                       [10] - Uranium (U-235) [Plutonium (See other diagram)]
                       [11] - Neutron Deflector (U-238)
                       [12] - Telemetry Monitoring Probes
                       [13] - Receptacle for U-235 upon detonation
                              to facilitate supercritical mass.
                       [14] - Fuses (inserted to arm bomb)
 

Diagram for Plutonium Bomb
Gravity Bomb - Implosion Model

Cutaway Sections Visible


 
                                      /\
                                     /  \ <---------------------------[1]
                                    /    \
                  _________________/______\_________________
                 | :      ||:      ~      ~               : |
     [2]-------> | :      ||:                             : |
                 | :      ||:                             : |
                 | :      ||:                             : |
                 | :      ||:                             : |
                 | :      ||:                             : |
                 | :      ||:                             : |
                 | :      ||:                             : |
                 | :      ||:                             : |
                 | :      ||:                             : |
                 | :      ||:                             : |
                 | :      ||:                             : |
                 | :______||:_____________________________: |
                 |/_______||/______________________________\|
                  \       ~\       | :          |:|         /
                   \       |\      | :          |:|        /
                    \      | \     | :__________|:|       /
                     \     |:_\    | :__________\:|      /
                      \    |___\   |______________|     /
                       \  |     \ |~               \   /
                        \|_______\|_________________\_/
                        |_____________________________|
                        /                             \
                       /                               \
                      /                                 \
                     /          _______________          \
                    /       ___/               \___       \
                   /____ __/                       \__ ____\
     [3]_______________________________               \ ___|
                   / __/               \               \__ \
                  / /                  \/                 \ \
                 / /              ___________              \ \
                / /            __/___________\__            \ \
              ./ /__  ___     /=================\     ___  __\ \.
     [4]-------> ___||___|====|[[[[[|||||||]]]]]|====|___||___ <------[4]
            /  /              |=o=o=o=o=o=o=o=o=| <-------------------[5]
           .' /                \_______ _______/                \ `.
           :  |___                    |*|                    ___|  :
          .'  |   \_________________  |*|  _________________/   |  `.
          :   |   ___________   ___ \ |*| / ___   ___________   |   :
          :   |__/           \ /   \_\\*//_/   \ /           \__|   :
          :   |______________:|:____:: **::****:|:********\ <---------[6]
         .'  /:|||||||||||||'`|;..:::::::::::..;|'`|||||||*|||||:\  `.
     [7]----------> ||||||' .:::;~|~~~___~~~|~;:::. `|||||*|| <-------[7]
         :   |:|||||||||' .::'\ ..:::::::::::.. /`::. `|||*|||||:|   :
         :   |:|||||||' .::' .:::''~~     ~~``:::. `::. `|\***\|:|   :
         :   |:|||||' .::\ .::''\ |   [9]   | /``::: /::. `|||*|:|   :
     [8]------------>::' .::'    \|_________|/    `::: `::. `|* <-----[6]
         `.  \:||' .::' ::'\ [9] .     .     . [9] /::: `::.  *|:/  .'
          :   \:' :::'.::'  \  .               .  /  `::.`::: *:/   :
          :    | .::'.::'____\    [10] . [10]    /____`::.`::.*|    :
          :    | :::~:::     |       . . .       |     :::~:::*|    :
          :    | ::: ::  [9] | .   . ..:.. .   . | [9]  :: :::*|    :
          :    \ ::: ::      |       . :\_____________________________[11]
          `.    \`:: ::: ____|     .   .   .     |____ ::: ::'/    .'
           :     \:;~`::.    / .  [10]   [10]  . \    .::'~::/     :
           `.     \:. `::.  /    .     .     .    \  .::' .:/     .'
            :      \:. `:::/ [9]   _________   [9] \:::' .:/      :
            `.      \::. `:::.   /|         |\   .:::' .::/      .'
             :       ~~\:/ `:::./ |   [9]   | \.:::' \:/~~       :
             `:=========\::. `::::...     ...::::' .::/=========:'
              `:         ~\::./ ```:::::::::''' \.::/~         :'
               `.          ~~~~~~\|   ~~~   |/~~~~~~          .'
                `.                \:::...:::/                .'
                 `.                ~~~~~~~~~                .'
                  `.                                       .'
                   `:.                                   .:'
                    `::.                               .::'
                      `::..                         ..::'
                        `:::..                   ..:::'
                          `::::::...        ..::::::'
    [12]------------------> `:____:::::::::::____:' <-----------------[12]
                              ```::::_____::::'''
                                     ~~~~~
 
 
                              - Diagram Outline -
                             ---------------------
 
                        [1] - Tail Cone
                        [2] - Stabilizing Tail Fins
                        [3] - Air Pressure Detonator
                        [4] - Air Inlet Tube(s)
                        [5] - Altimeter/Pressure Sensors
                        [6] - Electronic Conduits & Fusing Circuits
                        [7] - Lead Shield Container
                        [8] - Neutron Deflector (U-238)
                        [9] - Conventional Explosive Charge(s)
                       [10] - Plutonium (Pu-239)
                       [11] - Receptacle for Beryllium/Polonium mixture
                              to facilitate atomic detonation reaction.
                       [12] - Fuses (inserted to arm bomb)
 

File courtesy of Outlaw Labs
 
Understanding Electromagnetic Pulse
                                and
         How to Prevent Resulting Damage to Electrical Equipment
 
______________________________by Joe Bobier____________________________
 
One  of  the  many  fables of nuclear war that has been worn out in an
effort to convince us all of the futility  of  it  all  is  EMP.  When
understood, the problem can take on realistic proportions.
When  a  nuclear  explosion occurs, a very broad spectrum of energy is
released. It ranges from nearly  DC  (o  KHZ)  to  beyond  1021  hertz
(gamma  rays).  The  portion  concerned with here ranges from 0 KHZ to
1000 GHZ (beyond radar uses).
 
Two  basic  sorts  of  damage can occur as a result of EMP. The first being
what we will call " power line " type of damage, and the other  being  what
I'll  call  "  radio  "  damage.  Power  line  damage is resultant from the
induction of high levels of current into relatively long wires such as home
or shelter wiring, electrical generating system wiring such as  the  cables
running  to and from PV ( photovoltaic ) panels, generators, windmills, and
of course in the already famous auto electronic ignition system. This  type
of  damage  can  be  virtually  eliminated  by a multi-level approach, that
provides front line defenses, and various levels of backup systems  in  the
event  that  EMP  should  overcome the first level of defense. This layered
defense method has proven  highly  reliable  in  commercial  communications
systems  where radio towers are subject to severe direct lightning strikes.
Even with such severe EMP and direct surge  conditions  which  excede  most
predicted  EMP  conditions,  the  communications  systems survive often for
years of storm seasons.
 
The first layer of EMP defense is the THYZORB. This is a solid state single
junction device similar  to  an  avalanch  diode.  Its  maker  is  National
Semiconductor, and it is distributed by Square D. You should purchase these
devices  specifically  matched  to  the  type of system voltage you wish to
protect. For instance, if you wish to protect  a  12  VDC  PV  system,  you
should  consider  that the open circuit voltage of most PV panels is around
19 VDC so a 25 VD  C  THYZORB  would  provide  excellent  protection.  Also
remember  that  as  the  amount of current through the device increases, so
does the voltage drop across the device. Generally about 10 VDC  is  to  be
expected  at  maximum  rating,  thus we can expect that no more than 35 VDC
will develop at the protected area.
 
I would place a Thyzorb on each panel at the output terminals and then  one
more  at the junction of the panels where your main feed line is connected.
The THYZORB is available in many power  ratings  from  1.5  KW  to  15  KW.
Generally  you should be safe with the small ones on the panels, and the 15
KW unit at the junction point. At the other end of the feedline add another
THYZORB just as the first one at the junction point was.  The  device  only
has  two connections on it which are placed directly across the lines to be
protectedUnder  normal  conditions,  the  unit  has  no  effect  on  the
circuitryThe  unit  is  reliable  and  re-useable.  After  thousands  of
operations, it will still be as good as new. The reaction  time  for  those
who  wonder  about  such things is about 10 nano seconds. In the event your
cables are longer than ten feet or so, it wouldn't hurt to  add  a  THYZORB
every  ten  feet.  THYZORBS are available in many voltages and in AC or DC.
This means you should be installing them in any AC lines such  as  inverter
outputs  or  generator  outputs.  I  would put one in every wall outlet and
light fixture also. Now for the layered effect I mentioned earlier.
 
In the event the THYZORB fails you need to have another device in place  to
soak  up  the  balance of the surge. In low voltage DC systems your choices
are somewhat limited. You could use an MOV ( metal oxide varistor ).  These
are  devices  made by General Electric. They are widely available at stores
like Radio Shack. The only problem with MOV's is that every time they  fire
(see  a surge) they drift in value a little. Pretty soon your surge stopper
isn't turning on at the right time or worse yet fails  altogether.  In  low
voltage systems, you can't really use a gas discharge tube, since they only
work  at  150  volts  or higher. By then your low voltage equipment will be
fried. Instead, at the risk  of  sounding  redundant,  I  recomend  another
THYZORB  but selected at a slightly higher voltage. Five volts higher would
be a good choice since the second one would only fire if the first one were
working at 1/2 of its full capacity. This would  cause  a  current  sharing
condition  and  increase overall device reliability. You could in theory go
several layers in this manner until you felt completely safe,  or  you  ran
out  of  EMP  money.  The  actual  connections would be to earth ground the
negative (-) side of your DC power system in several  locations.  Use  long
bronze, brass, or copper rods with heavy, short cables to the power system.
Next  attach  the  negative (-) side of the protection device, ( THYZORB or
other ), to the ground system. Finally, attach the  positive  side  of  the
protection  device  to  the  positive  side  of  the power system. In an AC
system, you can do exactly the same as above with proper device  selection.
You may also use a gas discharge tube here since we are dealing with a high
voltage to start with. In this case you will have three wires to deal with;
one  for  each  side  of  the  AC,  and  one  for  earth ground. Additional
preventive measures include  grounding  the  frame  of  the  PV  panel  and
grounding  generator  frames.  A good earth ground is very important if you
use gas discharge tubes. If scenes from the " DAY AFTER " have you paranoid
about being trapped in an immobile car, then take heart. You can EMP  proof
your  auto  electrical  system  the same way as your low voltage DC system.
Just put a couple layers of THYZORBS or MOV's across the DC  input  to  the
ignition  system.  A few more sprinkled here and there like the power wires
of your CB radio, or your AM/FM receiver will work wonders. An easy way  to
reduce the risk of appliance damage in your home or shelter, if it is an AC
device  is to use a personal computer style surge protector. They are cheap
and very easy to install. Most of these devices use  MOV's  or  better  yet
THYZORBS or avalanch diodes.
 

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