Beta decay is a type of radioactive decay in which an unstable atomic nucleus transforms into a slightly lighter nucleus by emitting a beta particle, which can be either an electron (\( e^- \)) or a positron (\( e^+ \)). The atomic mass number (A) of the nucleus remains unchanged, but the atomic number (Z) increases by one, as a neutron is converted into a proton within the nucleus.

To illustrate, consider the decay of lead-211 (\( Pb-211 \)) into bismuth-211 (\( Bi-211 \)). Since a beta particle is an electron, and it is emitted from the nucleus, the atomic number of lead increases from 82 to 83, thereby becoming bismuth. The mass number remains 211 because this form of decay does not affect the number of nucleons (protons and neutrons) in the nucleus. The equation for this beta decay process is:
\( Pb-211 \rightarrow Bi-211 + e^- \).

Positron emission, also known as beta plus decay (\( \beta^+ \) decay), is a process where an unstable nucleus emits a positron (\( e^+ \))—the antimatter counterpart of the electron. In this decay mode, a proton is converted into a neutron, leading to a decrease in the atomic number by one while the mass number stays the same.

For example, when manganese-50 (\( Mn-50 \)) undergoes positron emission, it transforms into chromium-50 (\( Cr-50 \)). The atomic number decreases from 25 to 24 as a result of the positron emission, and since the mass number doesn't change, it remains at 50. The reaction is represented as follows:
\( Mn-50 \rightarrow Cr-50 + e^+ \).

Electron capture is a decay process where an inner-shell electron from the atom is captured by the nucleus, combining with a proton to form a neutron and emitting a neutrino (\( u_e \)). Similar to positron emission, this results in a decrease of the atomic number by one while the atomic mass number remains constant.

Take the decay of tungsten-179 (\( W-179 \)) into tantalum-179 (\( Ta-179 \)) as an example. An electron is captured by the nucleus, reducing the atomic number from 74 to 73 but keeping the mass number at 179. The resulting nucleus is tantalum-179, and the equation can be represented by:
\( e^- + W-179 \rightarrow Ta-179 + u_e \).

Alpha decay is one of the most common forms of radioactive decay wherein an alpha particle, consisting of two protons and two neutrons (\( ^4He \) nucleus), is emitted from an unstable parent nucleus. This results in a reduction of the atomic mass number by four and the atomic number by two.

An example of alpha decay is thorium-230 (\( Th-230 \)) decaying into radium-226 (\( Ra-226 \)). The thorium nucleus loses an alpha particle, leading to the new configuration with a decreased atomic number from 90 to 88 (radium) and a mass number reduced from 230 to 226. The alpha decay process is represented by:
\( Th-230 \rightarrow Ra-226 + ^4He \).