Alpha decay is a type of radioactive decay where an unstable atomic nucleus releases an alpha particle. An alpha particle consists of 2 protons and 2 neutrons, which is essentially a helium nucleus (denoted \(_2^4 \mathrm{He}\)). When alpha decay occurs:

• The atomic number decreases by 2.
• The atomic mass reduces by 4 units.

This process results in the creation of a new element. In the example provided, the element Radium \(_{88}^{222} \mathrm{Ra}\) undergoes alpha decay to form Radon \(_{86}^{218} \mathrm{Rn}\). Consequently, our understanding of alpha decay plays a crucial role in fields such as nuclear physics and radiometric dating.

Radioactive particles are tiny fragments emitted from a nucleus during radioactive decay. These particles include:

• Alpha particles: Consist of 2 protons and 2 neutrons. They are large and heavy compared to other particles.
• Beta particles: Essentially high-speed electrons or positrons that are ejected from the nucleus of an atom.
• Gamma rays: High-energy electromagnetic waves emitted from a nuclear transition.

These particles interact differently with matter. Alpha particles, for example, have a high ionization power due to their size but are not very penetrating. They can be stopped by a sheet of paper or human skin. Understanding the properties of these particles helps in applications ranging from nuclear medicine to energy production.

Nuclear reactions describe transformations involving changes in an atom's nucleus. In radioactive decay, a common type of nuclear reaction, unstable atoms spontaneously transform to become stable, releasing energy in the process. Key characteristics of nuclear reactions include:

• Involvement of the nucleus rather than the entire atom.
• Emission of particles like alpha or beta particles.
• Release of large amounts of energy compared to chemical reactions.

Nuclear reactions can be further categorized into processes like fission, fusion, and radioactive decay. Alpha decay, for instance, is a specific kind of radioactive decay. These reactions have substantial implications in areas such as nuclear energy, where the same principles apply in reactors that produce electricity by splitting nuclei in a controlled manner.