In commutative algebra, the mathematical study of commutative rings, adic topologies are a family of topologies on the underlying set of a module, generalizing the p-adic topologies on the integers.
Let R be a commutative ring and M an R-module. Then each ideal 𝔞 of R determines a topology on M called the 𝔞-adic topology, characterized by the pseudometric
With respect to the topology, the module operations of addition and scalar multiplication are continuous, so that M becomes a topological module. However, M need not be Hausdorff; it is Hausdorff if and only if
By Krull's intersection theorem, if R is a Noetherian ring which is an integral domain or a local ring, it holds that for any proper ideal 𝔞 of R. Thus under these conditions, for any proper ideal 𝔞 of R and any R-module M, the 𝔞-adic topology on M is separated.
For a submodule N of M, the canonical homomorphism to M/N induces a quotient topology which coincides with the 𝔞-adic topology. The analogous result is not necessarily true for the submodule N itself: the subspace topology need not be the 𝔞-adic topology. However, the two topologies coincide when R is Noetherian and M finitely generated. This follows from the Artin-Rees lemma.[2]
Main article: Completion (algebra) |
When M is Hausdorff, M can be completed as a metric space; the resulting space is denoted by and has the module structure obtained by extending the module operations by continuity. It is also the same as (or canonically isomorphic to):
For example, let be a polynomial ring over a field k and 𝔞 = (x1, ..., xn) the (unique) homogeneous maximal ideal. Then , the formal power series ring over k in n variables.[4]
As a consequence of the above, the 𝔞-adic closure of a submodule is [5] This closure coincides with N whenever R is 𝔞-adically complete and M is finitely generated.[6]
R is called Zariski with respect to 𝔞 if every ideal in R is 𝔞-adically closed. There is a characterization:
In particular a Noetherian local ring is Zariski with respect to the maximal ideal.[7]