3: Radioactivity and Nuclear Chemistry

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In today’s society, the term radioactivity conjures up a variety of images:

Nuclear power plants producing hydrocarbon-free energy, but with potentially deadly by-products that are difficult to store safely.
Bombs with the capacity to use nuclear reactions that produce devastating explosions with horrible side effects on the earth as we know it, and on the surviving populations that inhabit it.
Medical technology that utilizes nuclear chemistry to peer inside living things to detect disease, and the power to irradiate tissues to potentially cure these diseases.
Fusion reactors that hold the promise of limitless energy with few toxic side products.

Radioactivity has a colorful history and clearly presents a variety of social and scientific dilemmas. In this chapter we will introduce the basic concepts of radioactivity, nuclear equations, and the processes involved in nuclear fission and nuclear fusion.

3.1: The Discovery of Radioactivity
Henri Becquerel, Marie Curie, and Pierre Curie shared the discovery of radioactivity.
3.2: Types of Radioactivity- Alpha, Beta, and Gamma Decay
The major types of radioactivity include alpha particles, beta particles, and gamma rays. Fission is a type of radioactivity in which large nuclei spontaneously break apart into smaller nuclei.
3.3: Detecting Radioactivity
Several different devices are used to detect and measure radiation, including Geiger counters, scintillation counters (scintillators), and radiation dosimeters. Probably the best-known radiation instrument, the Geiger counter (also called the Geiger-Müller counter) detects and measures radiation. Radiation causes the ionization of the gas in a Geiger-Müller tube.
3.4: Half-Lives of Radioisotopes
During natural radioactive decay, not all atoms of an element are instantaneously changed to atoms of another element. The decay process takes time and there is value in being able to express the rate at which a process occurs. A useful concept is half-life, which is the time required for half of the starting material to change or decay. Half-lives can be calculated from measurements on the change in mass of a nuclide and the time it takes to occur.
3.5: Radiation Effects and Units
We are constantly exposed to radiation from naturally occurring and human-produced sources. This radiation can affect living organisms. Ionizing radiation is the most harmful type of radiation because it can ionize molecules or break chemical bonds, which damages the molecules and causes malfunctions in cell processes. Types of radiation differ in their ability to penetrate material and damage tissue.
3.6: Medical uses of radioisotopes
Applications of nuclear radiation in medical treatment, like medical imaging and killing of cancer cells using external or internal radiation sources, are introduced.
3.7: Making radioisotopes for medical uses
Production of radionuclides commonly used in medical therapies is introduced.

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