2006-07-25 13:28:50 · 11 answers · asked by danthesledman 1 in Science & Mathematics ➔ Engineering
This is a REALLY long answer. Visit the link for all the details on building your own nuke.
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 heights. However, changes in air pressure due to the weather can adversely affect the altimeter's readings. It 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 altimeter. Like simple pulse systems, signals are emitted from a radar aerial (the bomb), bounced off the ground and received back at the bomb's altimeter. This pulse system applies to the more advanced altimeter system, only the signal is continuous and centered around a high frequency such as 4200 MHz. This 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 MHz. By the time that pulse has returned, the altimeter transmitter will be emitting a higher frequency. The difference depends on how long the pulse has taken to do the return journey. When these two frequencies are mixed electronically, a new frequency (the difference between the two) emerges. The value of this new frequency is measured by the built-in microchips. This 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 second. Its 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 ranges. Being 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 used. At high altitudes, the air is of lesser pressure. As the altitude drops, the air pressure increases. A simple piece of very thin magnetized metal can be used as an air pressure detonator. All 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 detonation. Before 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 cap. It merely serves as a catalyst to bring about a greater explosion. Calibration of this device is essential. Too 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 metals. This 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 used. The 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 detonate. One very good explosive is Urea Nitrate. The directions on how to make Urea Nitrate are as follows:
Ingredients
1 cup concentrated solution of uric acid (C5 H4 N4 O3)
1/3 cup of nitric acid
4 heat-resistant glass containers
4 filters (coffee filters will do)
Filter the concentrated solution of uric acid through a filter to remove impurities. Slowly add 1/3 cup of nitric acid to the solution and let the mixture stand for 1 hour. Filter again as before. This time the Urea Nitrate crystals will collect on the filter. Wash the crystals by pouring water over them while they are in the filter. Remove the crystals from the filter and allow 16 hours for them to dry. This 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-238. Not 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 purposes. In 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 extract. In 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 detonation. To 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 characteristics. The 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-238. A system of gaseous diffusion is used to begin the separating process between the two isotopes. In this system, Uranium is combined with fluorine to form Uranium Hexafluoride gas. This mixture is then propelled by low- pressure pumps through a series of extremely fine porous barriers. Because the U-235 atoms are lighter and thus propelled faster than the U-238 atoms, they could penetrate the barriers more rapidly. As a result, the U-235's concentration became successively greater as it passed through each barrier. After 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 again. Magnetic separation of the extract from the previous enriching process is then implemented to further refine the Uranium. This involves electrically charging Uranium Tetrachloride gas and directing it past a weak electromagnet. Since 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 process. In this procedure, a gas centrifuge is brought into action to further separate the lighter U-235 from its heavier counter-isotope. Centrifugal force separates the two isotopes of Uranium by their mass. Once 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 one. Plutonium can be used in an atomic bomb as well. By 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 Uranium. While 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 packs. Along 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 parts. Larger mass is spherical and concave. Smaller mass is precisely the size and shape of the `missing' section of the larger mass. Upon detonation of conventional explosive, the smaller mass is violently injected and welded to the larger mass. Supercritical 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 mixture. These 32 sections together form a sphere. All of these sections must have the precisely equal mass (and shape) of the others. The shape of the detonator resembles a soccerball. Upon 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 bomb. The 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 payload. These 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 launched. The fuses should be installed only shortly before the bomb is launched. To affix them before it is time could result in an accident of catastrophic proportions.
2006-07-25 13:37:34 · answer #1 · answered by Anonymous · 0⤊ 0⤋
Go to college and learn alot about physics and engineering. Then get a job with the Department of Defence.
You can't just build one at home- you need materials that are radioactive and take an exceptional amount of work to process into weapon grade material. The amount of equipment and manpower to process enough uranium into fissionable bomb cores takes MILLIONS.
It's not an unreasonable question - just oen that every day people can't afford - and I'm very happy of that.
2006-07-25 13:35:09 · answer #2 · answered by Anonymous · 0⤊ 0⤋
Your prototypes failed, and you elect somebody to do your layout, attempting out and shape artwork for a weapon of mass destruction? this question shows which you're very far from having a practicable concept (no longer to show a weapon), or you have surely superior a "suitcase" gadget and are checking on the competition. In the two case you will maximum in all probability be answering multiple questions for some very unhappy human beings quickly. savour existence at the back of bars.
2016-11-03 00:06:15 · answer #3 · answered by bulman 4 · 0⤊ 0⤋
You surround the fissionable material in a fission bomb with heavy hydrogen, deuterium and tritium. Upon explosion due to the heat and pressure these fuse to create hydogen, giving off a truely unbelievable amount of energy. It is a fusion device.
See: Dr. Edward Teller
2006-07-25 13:52:36 · answer #4 · answered by helixburger 6 · 0⤊ 0⤋
Read "The Sum of All Fears", by Tom Clancy. He describes the construction of a nuclear device in detail. Really!
2006-07-25 13:33:13 · answer #5 · answered by Heckel 3 · 0⤊ 0⤋
step one: aquire a finnigan pin
step two: one quart of frequency grease
step three: build a 546 F flux capacitor
step four: shove all the above-listed equipment up your a-ss
2006-07-25 13:32:39 · answer #6 · answered by electronics,weights,firearms 3 · 0⤊ 0⤋
Basically, jam enough fissible material together under sufficient pressure.
2006-07-25 15:44:33 · answer #7 · answered by Anonymous · 0⤊ 0⤋
LOL watch out for some Black Suvs in your driveway buddy.
2006-07-25 13:31:08 · answer #8 · answered by matt83840 5 · 0⤊ 0⤋
WIth sprinkles and sunshine.
2006-07-25 13:32:39 · answer #9 · answered by OMG! PANCAKES LOLz! 2 · 0⤊ 0⤋
think this question got someones attention?i think so
2006-07-25 13:32:25 · answer #10 · answered by mjk6886@yahoo.com 3 · 0⤊ 0⤋
WHY? Terrorists!!!!!!!
2006-07-25 13:34:22 · answer #11 · answered by Anonymous · 0⤊ 0⤋