• The ring \mathbb{Z}/6\mathbb{Z} is not a domain, because the images of 2 and 3 in this ring are nonzero elements with product 0. More generally, for a positive integer n, the ring
\mathbb{Z}/n\mathbb{Z} is a domain if and only if n is prime. • A
finite domain is automatically a
finite field, by
Wedderburn's little theorem. • The
quaternions form a noncommutative domain. More generally, any
division ring is a domain, since every nonzero element is
invertible. • The set of all
Lipschitz quaternions, that is, quaternions of the form a+bi+cj+dk where
a,
b,
c,
d are integers, is a noncommutative subring of the quaternions, hence a noncommutative domain. • Similarly, the set of all
Hurwitz quaternions, that is, quaternions of the form a+bi+cj+dk where
a,
b,
c,
d are either all integers or all
half-integers, is a noncommutative domain. • A
matrix ring M
n(
R) for
n ≥ 2 is never a domain: if
R is nonzero, such a matrix ring has nonzero zero divisors and even
nilpotent elements other than 0. For example, the square of the
matrix unit E12 is 0. • The
tensor algebra of a
vector space, or equivalently, the algebra of polynomials in noncommuting variables over a field, \mathbb{K}\langle x_1,\ldots,x_n\rangle, is a domain. This may be proved using an ordering on the noncommutative monomials. • If
R is a domain and
S is an
Ore extension of
R then
S is a domain. • The
Weyl algebra is a noncommutative domain. • The
universal enveloping algebra of any
Lie algebra over a field is a domain. The proof uses the standard filtration on the universal enveloping algebra and the
Poincaré–Birkhoff–Witt theorem. == Group rings and the zero divisor problem ==