ideal class

Let $K$ be a number field. Let $𝔞$ and $𝔟$ be ideals in ${𝒪}_K$ (the ring of algebraic integers of $K$). Define a relation $\sim$ on the ideals of ${𝒪}_K$ in the following way: write $𝔞\sim 𝔟$ if there exist nonzero elements $\alpha$ and $\beta$ of ${𝒪}_K$ such that $(\alpha )𝔞=(\beta )𝔟$.

The relation $\sim$ is an equivalence relation, and the equivalence classes under $\sim$ are known as ideal classes.

The number of equivalence classes, denoted by $h$ or $h_K$, is called the class number of $K$.

Note that the set of ideals of any ring $R$ forms an abelian semigroup with the product of ideals as the semigroup operation. By replacing ideals by ideal classes, it is possible to define a group on the ideal classes of ${𝒪}_K$ in the following way.

Let $𝔞$, $𝔟$ be ideals of ${𝒪}_K$. Denote the ideal classes of which $𝔞$ and $𝔟$ are representatives by $[𝔞]$ and $[𝔟]$ respectively. Then define $\cdot$ by

Let $𝒞=\{[𝔞]\mid 𝔞\ne (0),𝔞\text{ an ideal of }{𝒪}_K\}$.With the above definition of multiplication, $𝒞$ is an abelian group, called the ideal class group (or frequently just the class group) of $K$.

Note that the ideal class group of $K$ is simply the quotient group of the ideal group of $K$ by the subgroup of principal fractional ideals.