Abbreviation: Fld
A \emph{field} is a commutative rings with identity $\mathbf{F}=\langle F,+,-,0,\cdot,1 \rangle$ such that
$\mathbf{F}$ is non-trivial: $0\ne 1$
every non-zero element has a multiplicative inverse: $x\ne 0\Longrightarrow \exists y (x\cdot y=1)$
Remark: The inverse of $x$ is unique, and is usually denoted by $x^{-1}$.
Let $\mathbf{F}$ and $\mathbf{G}$ be fields. A morphism from $\mathbf{F}$ to $\mathbf{G}$ is a function $h:F\rightarrow G$ that is a homomorphism:
$h(x+y)=h(x)+h(y)$, $h(x\cdot y)=h(x)\cdot h(y)$, $h(1)=1$
Remark: It follows that $h(0)=0$ and $h(-x)=-h(x)$.
Example 1: $\langle\mathbb{Q},+,-,0,\cdot,1\rangle$, the field of rational numbers with addition, subtraction, zero, multiplication, and one.
$0$ is a zero for $\cdot$: $0\cdot x=x$ and $x\cdot 0=0$.
$\begin{array}{lr}
f(1)= &0
f(2)= &1
f(3)= &1
f(4)= &1
f(5)= &1
f(6)= &0
\end{array}$
There exists one field, called the Galois field $GF(p^m)$ of each prime-power order $p^m$.