Let R be a ring and let G be a monoid. The monoid ring or monoid algebra of G over R, denoted R[G] or RG, is the set of formal sums ${\displaystyle \sum _{g\in G}r_{g}g}$ , where ${\displaystyle r_{g}\in R}$  for each ${\displaystyle g\in G}$  and r_g = 0 for all but finitely many g, equipped with coefficient-wise addition, and the multiplication in which the elements of R commute with the elements of G. More formally, R[G] is the free R-module on the set G, endowed with R-linear multiplication defined on the base elements by g·h := gh, where the left-hand side is understood as the multiplication in R[G] and the right-hand side is understood in G.

Alternatively, one can identify the element ${\displaystyle g\in R[G]}$  with the function e_g that maps g to 1 and every other element of G to 0. This way, R[G] is identified with the set of functions φ: G → R such that {g : φ(g) ≠ 0} is finite. equipped with addition of functions, and with multiplication defined by

${\displaystyle (\phi \psi )(g)=\sum _{k\ell =g}\phi (k)\psi (\ell )}$ .

If G is a group, then R[G] is also called the group ring of G over R.

Given R and G, there is a ring homomorphism α: R → R[G] sending each r to r1 (where 1 is the identity element of G), and a monoid homomorphism β: G → R[G] (where the latter is viewed as a monoid under multiplication) sending each g to 1g (where 1 is the multiplicative identity of R). We have that α(r) commutes with β(g) for all r in R and g in G.

The universal property of the monoid ring states that given a ring S, a ring homomorphism α': R → S, and a monoid homomorphism β': G → S to the multiplicative monoid of S, such that α'(r) commutes with β'(g) for all r in R and g in G, there is a unique ring homomorphism γ: R[G] → S such that composing α and β with γ produces α' and β '.

The augmentation is the ring homomorphism η: R[G] → R defined by

${\displaystyle \eta \left(\sum _{g\in G}r_{g}g\right)=\sum _{g\in G}r_{g}.}$ 

The kernel of η is called the augmentation ideal. It is a free R-module with basis consisting of 1 – g for all g in G not equal to 1.

Given a ring R and the (additive) monoid of natural numbers N (or {xⁿ} viewed multiplicatively), we obtain the ring R[{xⁿ}] =: R[x] of polynomials over R. The monoid Nⁿ (with the addition) gives the polynomial ring with n variables: R[Nⁿ] =: R[X₁, ..., X_n].

If G is a semigroup, the same construction yields a semigroup ring R[G].

• Free algebra
• Puiseux series

• Lang, Serge (2002). Algebra. Graduate Texts in Mathematics. Vol. 211 (Rev. 3rd ed.). New York: Springer-Verlag. ISBN 0-387-95385-X.

• R.Gilmer. Commutative semigroup rings. University of Chicago Press, Chicago–London, 1984