РефератыИностранный языкAtAtomic Bomb Essay Research Paper During wartime

Atomic Bomb Essay Research Paper During wartime

Atomic Bomb Essay, Research Paper


During wartime, horrible atrocities against


all of humanity must be dealt with. Crimes against humanity,


as never witnessed before, and hopefully to never be seen again, occurred


during the course of World War II. America has always, and


most likely will always place a high value on American lives.


In order to protect these lives and to insure that the world is safe for


democracy, American leaders had to make a very tough decision, whether


or not to drop the atomic bomb on Japan. This act would essentially


trade Japanese lives for American lives. The Japanese were


responsible for hundreds of thousands of American casualties in the Pacific,


including the unprovoked attack on Pearl Harbor. With Japanese


forces showing no signs of surrender, American leaders made a decision.


This decision essentially changed the history of warfare forever.


An atomic bomb is any weapon that gets


its destructive power from an atom. This power comes when the matter


inside of the atoms is transformed into energy. The process by which


this is done is known as fission. The only two atoms suitable for


fission are the uranium isotope U-235 and the plutonium isotope Pu-239.


Fission occurs when a neutron, a subatomic particle with no electrical


charge, strikes the nucleus of one of these isotopes and causes it to split


apart. When the nucleus is split, a large amount of energy is produced,


and more free neutrons are also released. These neutrons strike other


atoms, which causes more energy to be released. If this process is


repeated, a self-sustaining chain reaction will occur, and it is this chain


reaction that causes the atomic bomb to have its destructive power.


The first type of atomic bomb ever used


was a gun-type. In this type two subcritical pieces of U-235 are


placed in a device similar to the barrel of an artillery shell. One


piece is placed at one end of the barrel and will remain there at rest.


The other subcritical mass is placed at the other end of the barrel.


A conventional explosive is packed behind the second subcritical mass.


When the fuse is triggered, a conventional explosion causes the second


subcritical mass to be propelled at a high velocity into the first subcritical


mass. The resulting combination causes the two subcritical masses


to become a supercritical mass. When this supercritical mass is obtained,


a rapid self-sustained chain reaction is caused. This type of atomic


bomb was used on Hiroshima, and given the nickname ?Little Boy? after Franklin


D. Roosevelt.


The second type of atomic bomb is an implosion


bomb. In this type a subcritical mass, which is in the shape of a


ball, is placed in the center of the weapon. This subcritical mass


is surrounded in a spherical arrangement of conventional explosives.


When the fuse is triggered all of the conventional explosives explode at


the same time. This causes the subcritical mass to be compressed


into a smaller volume, thus creating a supercritical mass to be formed.


After this supercritical mass is obtained, a self-sustained chain reaction


takes place and causes the atomic explosion. This type of atomic


bomb was used on Nagasaki, and given the nickname ?Fat Man? after Winston


Churchill.


The blast from an atomic bomb?s explosion


will last for only one-half to one second, but in this amount of time a


great deal of damage is done. A fireball is created by the blast,


which consists mainly of dust and gasses. The dust produced in this


fireball has no substantial effect on humans or their environment.


However, as the gasses expand a blast wave is produced. As this blast


wave moves, it creates static overpressure. This static overpressure


then in turn creates dynamic pressure. The static overpressure has


the power to crush buildings. The dynamic pressure creates winds,


which have the power to blow down trees. The blast pressure and fireball


together only last for approximately eleven seconds, but because it contains


fifty percent of the atomic bomb?s latent energy a great deal of destruction


occurs.


In Hiroshima, the blast from the atomic


bomb was measured to be about four and a half to six and seven tenths tons


of pressure per square meter, while in Nagasaki the blast was measured


to be about six to eight tons of pressure per square meter. Because


of this dramatic change in the pressure most of the cities were destroyed.


The static overpressure in Hiroshima destroyed between sixty-two and ninety


thousand buildings, while in Nagasaki all of the buildings within three


thousand feet of the center of the blast were completely destroyed.


The static overpressure created a dynamic pressure that had winds up to


four hundred miles per hour. These winds caused minor scratches,


lacerations, or compound fractures, which came about when people and glass


fragments were projected through the air. By combining the results


of the static overpressure and the dynamic pressure one can begin to see


what damage was caused by the atomic bomb?s blast.


The thermal radiation produced by an atomic


bomb explosion will account for thirty-five percent of the atomic bomb?s


damage. Thermal radiation can come in one of three forms: ultraviolet


radiation, visible radiation, or infrared radiation. The ultraviolet


radiation is absorbed so rapidly by air particles that it has no substantial


effect on people. However, the visible and infrared radiation creates


an enormous amount of heat to be produced, approximately ten million degrees


Celsius at the hypocenter. This heat has two main effects.


The first is known as flash burns. The flash of thermal radiation


produces these flash burns right after the explosion. Flash burns


can be either first-degree burns (bad sun burns), second-degree burns (blisters,


infections, and scars), or third-degree burns (destroyed skin tissue).


The second type is known as flame burns. These are burns that come


from one of two different types of fires, which are created when flammable


materials are ignited by the thermal radiation. The first type is


called firestorms. A firestorm is violent, has raging winds, and


has extremely high temperatures; but fortunately it does not spread very


rapidly. The second type is called a conflagration. A conflagration


is when the fire spreads in a front. The thermal radiation produced


by the atomic bomb?s explosion will account for most of the deaths or injuries.


In Hiroshima and Nagasaki the thermal


radiation accounted for approximately twenty to thirty percent of the deaths


or injuries from the atomic bomb?s explosion. Those that were at


a distance of two and one half miles from the hypocenter received first


degree burns. Those that were at a distance of two and one quarter


miles from the hypocenter received second degree burns. Those that


were at a distance of one half of a mile from the hypocenter received third


degree burns. Ninety-five percent of the burns created from the thermal


radiation were by flash burns, and only five percent of the burns were


by flame burns. The reason for this low number of flame burns is


that only two to ten percent of the buildings caught on fire. By


combining the damage from both the flash and flame burns one can begin


to see the effects that an atomic bomb?s thermal radiation had. Approximately


sixty thousand in Hiroshima, and approximately forty-one thousand people


were either killed or injured from the thermal radiation.


The final effect that an atomic bomb caused


is the nuclear radiation produced from the fission process. The nuclear


radiation comes in the form of either Gamma rays or Beta particles.


Gamma rays are electromagnetic radiation originating in the atomic nuclei,


physically identical to x-rays. They can enter into living tissue


extremely easily. Beta particles are negatively charged particles,


identical to an electron moving at a high velocity. These forms of


nuclear radiation are measured in rads (radiation-absorbed-dose), which


is defined as the absorption of five ten millionths joule per gram of absorbing


material. During the initial nuclear radiation mostly Gamma rays


are emitted from the fireball. This period of initial nuclear radiation


lasts for approximately one minute. During the residual nuclear period


(fallout) the Beta particles and more of the Gamma rays are emitted.


The residual radiation has two stages: early fallout and delayed fallout.


In early fallout, the heavy and highly radioactive particles fall back


to the earth, usually within the first twenty-four hours. In delayed


fallout, the tiny and often invisible particles fall back to the earth,


and usually last from a couple of days to several years. The nuclear


radiation from the atomic bomb?s explosion was not the main cause of death,


but it did still have serious results.


In Hiroshima, the initial nuclear radiation


was spread over a distance of approximately fifty-three hundredths of a


kilometer. In Nagasaki, the initial nuclear radiation only spread


one and six thousandths of a kilometer. The reason why the nuclear


radiation was not the main caused of deaths or injuries was that the atomic


bomb was detonated so high in the atmosphere; approximately five hundred


and seventy meters in Hiroshima, and approximately five hundred and ten


meters in Nagasaki. Even without causing many deaths the nuclear


radiation probably caused the most serious effects. Those with definite


proof were those of increased rates of cataracts, leukemia, cancer of the


thyroid, cancer of the breast, cancer of the lungs, cancer of the stomach,


and mental retardation of babies. Those that had substantial but


not definite proof were those of tumors of the esophagus, tumors of the


colon, tumors of the salivary glands, and tumors of the urinary tract organs.


Those that had no definite or substantial proof were those of increased


rates of birth mortality, birth defects, infertility, and susceptibility


towards illnesses.


The blast, the thermal radiation, or the


nuclear radiation from an atomic bomb explosion will have severe effects


on both humans and on the environment in which they live in. The


only two cities that have ever experienced having an atomic bomb being


exploded on them were the Japanese cities of Hiroshima and Nagasaki during


World War II. In Hiroshima, the casualties have been estimated between


seventy-five and eighty thousand. In Nagasaki, the total number killed


was estimated at more that thirty-five thousand. The total number


severely injured was even greater than forty thousand.


In the 50 years since the first atomic


explosion, the promises and perils of nuclear science have touched nearly


every aspect of our culture and politics. The scientific development


surrounding the A-bomb has been a pivotal point in the world’s history,


launching us into the Atomic Age. We came close to nuclear inhalation


during the cold war, but its benefits have been much greater. We


have turned nuclear power into a reliable source of energy, and it has


provided us with many technological advances. In the future we can


look forward to using the technology discovered during the Manhattan Project


to create even better sources of energy. We are only at the beginning


of the Atomic Age, and there are endless possibilities for the future.

Сохранить в соц. сетях:
Обсуждение:
comments powered by Disqus

Название реферата: Atomic Bomb Essay Research Paper During wartime

Слов:2000
Символов:13573
Размер:26.51 Кб.