Quasi-Frobenius ring

In ring theory, the class of Frobenius rings and their generalizations are the extension of work done on Frobenius algebras. Perhaps the most important generalization is that of quasi-Frobenius rings (QF rings), which are in turn generalized by right pseudo-Frobenius rings (PF rings) and right finitely pseudo-Frobenius rings (FPF rings). Other diverse generalizations of quasi-Frobenius rings include QF-1, QF-2 and QF-3 rings.

These types of rings can be viewed as descendants of algebras examined by Georg Frobenius. A partial list of pioneers in quasi-Frobenius rings includes R. Brauer, K. Morita, T. Nakayama, J. Nesbitt, and R.M. Thrall.

Contents

Definitions

For the sake of presentation, it will be easier to define quasi-Frobenius rings first. In the following characterizations of each type of ring, many properties of the ring will be revealed.

A ring R is quasi-Frobenius if and only if R satisfies any of the following equivalent conditions:

  1. R is Noetherian on one side and self-injective on one side.
  2. R is Artinian on a side and self-injective on a side.
  3. All right (or all left) R modules which are projective are also injective.
  4. All right (or all left) R modules which are injective are also projective.

A Frobenius ring R is one satisfying any of the following equivalent conditions. Let J=J(R) be the Jacobson radical of R.

  1. R is quasi-Frobenius and the socle \mathrm{soc}(R_R)\cong R/J as right R modules.
  2. R is quasi-Frobenius and \mathrm{soc}(_R R)\cong R/J as left R modules.
  3. As right R modules \mathrm{soc}(R_R)\cong R/J, and as left R modules \mathrm{soc}(_R R)\cong R/J.

For a commutative ring R, the following are equivalent:

  1. R is Frobenius
  2. R is QF
  3. R is a finite direct sum of local artinian rings with simple socles. (Such rings are examples of "zero-dimensional Gorenstein local rings".)

A ring R is right pseudo-Frobenius if any of the following equivalent conditions are met:

  1. Every faithful right R module is a generator for the category of right R modules.
  2. R is right self-injective and is a cogenerator of Mod-R.
  3. R is right self-injective and is finitely cogenerated as a right R module.
  4. R is right self-injective and a right Kasch ring.
  5. R is right self-injective, semilocal and the socle soc(RR) is an essential submodule of R.
  6. R is a cogenerator of Mod-R and is a left Kasch ring.

A ring R is right finitely pseudo-Frobenius if and only if every finitely generated faithful right R module is a generator of Mod-R.

Thrall's QF-1,2,3 generalizations

In the seminal article (Thrall 1948), R. M. Thrall focused on three specific properties of (finite dimensional) QF algebras and studied them in isolation. With additional assumptions, these definitions can also be used to generalize QF rings. A few other mathematicians pioneering these generalizations included K. Morita and H. Tachikawa.

Following (Anderson & Fuller 1992), let R be a left or right Artinian ring:

(In other words, R = End(M) = End(N). In general, it is possible for an endomorphism ring to strictly contain R.)

The numbering scheme does not necessarily outline a hierarchy. Under more lax conditions, these three classes of rings may not contain each other. Under the assumption that R is left or right Artinian however, QF-2 rings are QF-3. There is even an example of a QF-1 and QF-3 ring which is not QF-2.

Examples

See also

Notes

The definitions for QF, PF and FPF are easily seen to be categorical properties, and so they are preserved by Morita equivalence, however being a Frobenius ring is not preserved.

For one-sided Noetherian rings the conditions of left or right PF both coincide with QF, but FPF rings are still distinct.

A finite dimensional algebra R over a field k is a Frobenius k-algebra if and only if R is a Frobenius ring.

QF rings have the property that all of their modules can be embedded in a free R module. This can be seen in the following way. A module M embeds into its injective hull E(M), which is now also projective. As a projective module, E(M) is a summand of a free module F, and so E(M) embeds in F with the inclusion map. By composing these two maps, M is embedded in F.

Textbooks

References

For QF-1, QF-2, QF-3 rings: