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History Of Nuclear Energy Essay Research Paper

History Of Nuclear Energy Essay, Research Paper


The nuclear age began in Germany, in the 1930s in the lab of chemist


Otto Hahn.


Hahn was attempting to produce radium (In great need during the war) by


bombarding uranium atoms with neutrons. To his surprise, he ended up with


a much lighter element, barium.


That was 1938, This started the race for the power of the atom. Just


four years later Canada entered nuclear age in cooperation with the british.


Wartime, 1942: The British wanted a safe place to conduct nuclear


experiments; Since their country feared invasion by the nazi’s or bombing


attacks, Canada provided the haven the british needed in return for a


opportunity to work in the project.


The leader of the team that crossed the atlantic to Canada was Hans von


Halban, who along with Dr. Lew Kowarski had escaped from the Institute Du


Radium in Paris one step ahead of the invading german army. They took the


world supply of 200 Kg of heavy water with them to Canada.


Having pioneered the chain reaction using uranium and heavy water, the


scientists applied their knowledge and their heavy water to the new


Canadian nuclear industry.


On September 5th, 1945 near Ottawa the team started up the first


operating nuclear reactor outside the USA. Of course, the output was


minuscule, but the significance was immense; the principal of getting


energy from splitting atoms in a controlled chain reaction (fission) was


established beyond doubt. It was now the job of the scientists and


engineers to put it to a practical use.


Nuclear Reactors


A nuclear reactor is a device which produces heat. In a nuclear power


station, the reactor performs the same function as a boiler in a


conventional coal, gas or oil-fired station. Whether from a conventional


boiler or a nuclear reactor, heat is required to turn water into steam. The


steam is used to spin large turbines which in turn drive generators that


produce electricity. A reactor creates heat by splitting uranium atoms.


This is called ‘Nuclear reaction’ or ‘Fission’.


When the nucleus of an uranium atom is stuck by a neutron travelling at


the right speed, it splits into fragments which separate rapidly and


generate heat. It also gives off a few, new neutrons. In order to sustain a


continuous nuclear reaction, the speed of these neutrons must be slowed


down, or moderated. CANDU reactors use heavy water (Deuterium Oxide is


called heavy water because it is heavier than normal water by about 10%),


Thus the reactor is named CANDU, for (CAN)ada (D)euterium (U)ranium.


During Fission (the process used in nuclear reactors) some of the atom


breaks up, and energy is released. On average, 80% of the released energy


is carried off by the fragments in the form of kinetic energy. The other


20% is collected by the heavy water in the form of heat.


The core of a CANDU reactor


The core of a reactor is contained in a large cylindrical tank called


the ‘Calandria’. The calandria contains a series of tubes that run from one


end of the calandria to the other. Inside the calandria tubes are smaller


tubes which house fuel bundles containing natural uranium in the form of


ceramic pellets.


Heavy water is also used as the reactor coolant and is pumped through


the tubes containing the fuel pellets to pick up heat generated from the


reaction. The heated, heavy water travels to heat exchangers to produce


steam from ordinary water. This cooled heavy water is recycled back to the


reactor. The steam is then piped to conventional turbines and generators


that produce electricity. In this way the nuclear reactor is separate from


the equipment used to produce electricity.


Viable solutions for Energy needs


Annually, the demand for energy in Ontario increases by 5%. In response


to this increase, Hydro companies around Canada facing similar situations


have the responsibility of meeting the increase, usually by adding to their


arsenal of generators. The question which is brought up at this point is


how to do this most effectively in terms of impact on the environment, cost,


efficiency and several other aspects. In the case of Ontario Hydro, they


have chosen to expand on the method which appears to be best: nuclear power.


(Note: All of the following data on nuclear generating stations is based


on information on Canada’s CANDU plants.)


There are four main competitors in the energy race, but only two of


them are ‘technically viable’ Those right now are Nuclear and fossil fuels.


Of the other two, Solar energy is in limited use at the moment to things


like Solar calculators, or Solar cells used to supplement energy needs in a


large building. To collect 10^14 kWh (kilo-watt hours) (Average reactor


output) per year with solar cells, they would take up 1% of the earths


total land surface, or a area comparable in size to Western Europe!


Wind energy is an unviable solution because, the wind is not a constant


energy, unlike fossil fuels or nuclear. Another problem with wind energy,


is that it would take a space as big, or bigger than Western Europe to


place all the wind collectors to generate the electricity.


The problem with fossil fuels is demonstrated below. this makes Nuclear


energy the best solution for the worlds energy needs.


Energy sources such as fossil fuels (coal, etc.), and nuclear, emits by?


products which are often harmful to much of the environment. However,


nuclear plants are considerably less harmful than coal burning plants in


this respect. 1 tonne of coal used in coal burning plant produces 2.5


tonnes of carbon dioxide (which harms the environment in more ways than


one), 45 kilograms of acid rain (coming from the plant’s SO2 and NOx


emissions) and 90 kilograms of ash. In comparison of emissions, nuclear


plants are harmful as well, but are not harmful to this degree.


One harmful by-product which is virtually unique to nuclear plants is


’spent nuclear fuel’ coming from the fission reaction. Much of the waste


from nuclear plants is radioactive. Coal plants produce radioactive waste


as well, but the amount i

s so small that it is not insignificant. While


coal burning plants produce 450 grams of radioactive residue per 90


kilograms, 9 kilograms of radioactive residue are produced from 90


kilograms of ’spent nuclear fuel’. From this it is possible to see that


nuclear plants produce 20 times as much radioactive waste as coal plants do.


Radioactive waste is widely considered to be nuclear plants’ biggest


problem, currently. More specifically, the problem of storage and handling


of it has not yet been permanently taken care of. Meanwhile, temporary


storage sites carry the radioactive waste until a later time when permanent


locations might be found. Research is still being done on what methods


should be used to store the waste over long periods of time.


It is feared that the idea of keeping it inside containers buried


beneath the ground will be faulty since the containers may break with time


or when occasional earthquakes hit. Radioactive waste does, however, become


stable after several hundreds of years.


One solution for the disposal of nuclear plant waste draws a large


amount of criticism. Tritium produced in the fission reactions in Canadian


plants is sold to the United States for use in their nuclear weapons. Many


people object to this as they do not wish to support the use of nuclear


weapons.


Nuclear energy is extremely efficient when compared with coal burning


plants. 1 tonne of coal produces the same amount of energy as 50 grams of


nuclear fuel. Since mining is often a very disruptive process to the


environment around the mining operation, this relatively small amount of


fuel needed is better for the preservation of some land.


Public Concerns


The public and the workers who operate nuclear plants have concerns


about the amount of radiation which they are receiving. Radiation is


measured in millirem. Any dose of radiation is considered safe if it is


under 3500 millirem. Operators of the plants usually only receive 700


millirem per year, as long as there are no problems. This dose is 20% of


the 3500 millirem limit. Office staff on the site receive less than 20


millirem per year (which is equal to the amount of radiation received by a


person living 4 months in Denver). Should a person live at the fence of a


station, the dose would be equal to that of a round trip (flight) between


Toronto and Vancouver: 5 millirem. Residents living closest to nuclear


stations only receive 3 millirem per year, however. Also the amount of


radiation coming directly from fission of 1 Lb of Uranium 238 is the same


as the combustion of 6000 barrels of oil, or 1000 tons of oil. When


presented with these facts, I am in support of nuclear power. Overall the


effects to the environment are less, and if the spent nuclear fuel is taken


care of appropriately, I only see benefits for the world with nuclear power.


In the case of the Chernobyl meltdown in April 1986, one of the


generation site’s 4 units failed, which was because of poor design. The


remaining 3 units should be out of service soon, however, another 9 units


of the same design are still in operation. A similar accident is not


likely to happen in a CANDU plant because of the many fail safe devices.


Nuclear Energy and It’s Costs


Large generators such as nuclear and fossil fuel plants often cost


several billions of dollars. In terms of cost, nuclear stations cost


considerably more than fossil fuel stations to begin with. The Darlington


nuclear generating station (with 4 units) is currently having construction


completed. When it was first planned, Darlington was to cost $2.5 billion.


After 7 revisions of this price, it is 5 times higher at $12.63 billion. In


contrast, a fossil fuel plant would cost approximately $7 billion.


However, in operation, nuclear stations do not cost as much as fossil


fuel ones do. On April 7th, 1990, the distribution of energy sources, and


their prices went as follows:


Kilowatt hours of electricity Source Cost


($) —————————————————————- 157


561 000 Nuclear 1 016 268 102 399 000


Fossil fuel 3 870 272 113 630 000


Water 153 400


37 856 000 Purchased 979 296


411 446 000 Total $6 019 296 ———-


—————————————————— (1 kilowatt = 1000


watts. 1 kilowatt hour = 1 kilowatt per hour of use.)


Clearly, although nuclear generation was used on this day more than


fossil fuel generators, the operation of the fossil fuel ones was more


expensive.


The difference between the initial costs of nuclear ($12.63 billion)


and fossil ($7 billion) stations is $5.63 billion. However, since nuclear


plants cost considerably less in operation ($0.79 billion yearly), this


difference is paid for after several years of use. At $0.79 billion being


saved annually, the difference of $5.63 billion is met in roughly 7.1 years


of operation. As nuclear plants normally last for approximately 40 years,


at the end of this time one nuclear plant will have saved $31.6 billion


dollars for energy consumers. In terms of cost, nuclear power is less


expensive than other sources which can equal its amount of energy output


(water, for instance, cannot). Nuclear Plants do not create a lot of jobs


directly but because of money big industries may be able to save because of


nuclear energy more money can be put into hiring.


Summary


Of the energy sources that can currently be used on a large scale, none


are harmless to the environment and none are extremely inexpensive. Nuclear


energy is far from a perfect source, but no source of this size is. While


people wait for advancements in energy technology (such as cold fusion or


efficient solar and wind generation), with all aspects considered, nuclear


plants can supply the public with energy in the best possible way.


Bibliography


Atomic energy council of Canada.


“Nuclear facts” Toronto: AEC, 1989.


“Understanding Nuclear power” Toronto: AEC, 1989.


“What is Radiation?” Toronto: AEC, 1988.


“CANDU Operations” Toronto: AEC, 1988.


“A Journalists guide to nuclear power” Toronto:


Ontario Hydro, 1988.

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