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Applications of Nuclear Energy

Electric Power Generation

Medicine

Scientific Research

Food & Agriculture

Consumer Products

Industrial Applications

Space

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Nuclear Fission

Nuclear plants produce electricity by boiling water into steam.

This steam then turns turbines to produce electricity.

The difference is that nuclear plants do not burn anything.

Instead, they use uranium fuel, consisting of solid ceramic pellets, to produce

electricity through a process called fission.

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Nuclear Fusion Process

It is called 'fusion' because it is based on fusing light nuclei such as hydrogen isotopes to release energy, similar to that which powers the sun and other stars.

Nuclei of two isotopes of hydrogen, deuterium (D) and tritium (T) react to produce

a helium (He) nucleus and a neutron (n). In each reaction, 17.6 MeV of energy

(2.8 pJ) is liberated:

D + T →4He (3.5 MeV) + n (14.1 MeV)

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Nuclear Energy Scenario

435 Nuclear Power plants worldwide

1/6 of the worlds power is nuclear

France 76%, Belgium 56%, South Korea 36%, Switzerland 40%, Sweden 47%, Finland 30%, Japan 33%, United Kingdom 25%, Bulgaria 46%, Hungry 42%, United States 20%

WEC energy consumption doubled by 2050

World will turn to Fission Energy

Produces very small amount of spent fuel

6yrs of operation, 4-meter cube

Recyclable

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General Working of Nuclear Power Plant

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Medical

In nuclear medicine, medical professionals inject a tiny amount of a

radioisotope—a chemical element that produces radiation—into a

patient’s body.

A specific organ picks up the radioisotope, enabling a special camera to

take a detailed picture of how that organ is functioning.

For example: Myocardial perfusion imaging maps the blood flow to the

heart, allowing doctors to see whether a patient has heart disease and

determine the most effective course of treatment.

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Medical

Bone scans can detect the spread of cancer six to 18 months earlier

than X-rays.

Kidney scans are much more sensitive than X-rays or ultrasounds in

fully evaluating kidney function.

Imaging with radioactive technetium-99 can help diagnose bone

infections at the earliest possible stage.

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Research

The U.S. Food and Drug Administration requires all new drugs to be

tested for safety and effectiveness. More than 80 percent of those drugs

are tested with radioisotopes.

Radioisotopes also are essential to the biomedical research that seeks

causes and cures for diseases such as AIDS, Cancer and Alzheimer’s

disease.

Researchers also use radioisotopes in metabolic studies, genetic

engineering and environmental protection studies.

Carbon-14, a naturally occurring, long-lived radioactive substance, allows

archaeologists to determine when artefacts containing plant or animal

material were alive, created or used.

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Food & Agriculture

Food irradiation kills bacteria, insects and parasites that can cause food-

borne diseases, such as trichinosis and cholera.

According to the U.S. Department of Agriculture, more than 76 million

Americans are affected by food-borne illnesses each year, and more than

5,000 die.

In addition to killing bacteria, irradiation can retard spoilage and increase

the shelf life of food.

Food irradiation does not make the food radioactive, and it does not

change the food any more than canning or freezing.

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By the end of the 1980s, radiation had eradicated approximately 10

species of pest insects in wide areas, preventing agricultural

catastrophes. These pests included the Mediterranean fruit fly and the

screwworm fly.

Agricultural researchers also use radiation to:

develop hundreds of varieties of hardier, more disease-resistant crops—

including peanuts, tomatoes, onions, rice, soybeans and barley

improve the nutritional value of some crops, as well as improve their

baking or melting qualities or reduce their cooking time

show how plants absorb fertilizer, helping researchers to learn when to

apply fertilizer, and how much to use; this prevents overuse, thus reducing

a major source of soil and water pollution.

Food & Agriculture

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Consumer Products

Smoke Detector

• Ionization of air by a radioactive source

produces a current.

• Smoke traps the electrons and reduces the

current.

• Setting off the alarm.

• Many smoke detectors—installed in nearly 90

percent of U.S. homes—rely on a tiny

radioactive source to sound an alarm when

smoke is present.

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Consumer Products

Watches and clocks that “glow in the dark” use a small quantity of a radioisotope

as a source of light.

Computer disks “remember” data better when treated with radioisotopes

Treating nonstick pans with radiation ensures that the coating will stick to the

surface

Photocopiers use small amounts of radiation to eliminate static and prevent paper

from sticking together and jamming the machine

Radiation sterilizes cosmetics, hair products and contact lens solutions, removing

irritants and allergens Radiation sterilizes medical bandages and a variety of

personal health and hygiene products.

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Industrial Applications

The industries that use radioisotopes include:

―The automobile industry, to test the quality of steel in vehicles

―Aircraft manufacturers, to check for flaws in jet engines

―Mining and petroleum companies, to locate and quantify oil,

natural gas and mineral deposits

―Can manufacturers, to obtain the proper thickness of tin and

aluminum

―Pipeline companies, to look for defects in welds

―Construction crews, to gauge the density of road surfaces and

subsurfaces.

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Space

Unmanned spacecraft rely on radioisotope thermoelectric generators

(RTGs) for the power they need for space exploration.

RTGs use heat from Plutonium to generate electricity.

The craft use this electricity to run the computers that control their

operation and collect and process the vast amounts of data, including

images, that are sent back to Earth.

A typical RTG produces about 300 watts of electricity and will operate

unattended for many years.

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