Von Neumann regular ring

In mathematics, a von Neumann regular ring is a ring R such that for every a in R there exists an x in R such that a = axa. To avoid the possible confusion with the regular rings and regular local rings of commutative algebra (which are unrelated notions), von Neumann regular rings are also called absolutely flat rings, because these rings are characterized by the fact that every left module is flat.

One may think of x as a "weak inverse" of a. In general x is not uniquely determined by a.

Von Neumann regular rings were introduced by von Neumann (1936) under the name of "regular rings", during his study of von Neumann algebras and continuous geometry.

An element a of a ring is called a von Neumann regular element if there exists an x such that a = axa.[1] An ideal is called a (von Neumann) regular ideal if it is a von Neumann regular non-unital ring, i.e. if for every element a in there exists an element x in such that a = axa.[2]

Examples

Every field (and every skew field) is von Neumann regular: for a ≠ 0 we can take x = a−1.[1] An integral domain is von Neumann regular if and only if it is a field.

Another example of a von Neumann regular ring is the ring Mn(K) of n-by-n square matrices with entries from some field K. If r is the rank of A ∈ Mn(K), then there exist invertible matrices U and V such that

(where Ir is the r-by-r identity matrix). If we set X = V−1U−1, then

More generally, the matrix ring over a von Neumann regular ring is again a von Neumann regular ring.[1]

The ring of affiliated operators of a finite von Neumann algebra is von Neumann regular.

A Boolean ring is a ring in which every element satisfies a2 = a. Every Boolean ring is von Neumann regular.

Facts

The following statements are equivalent for the ring R:

The corresponding statements for right modules are also equivalent to R being von Neumann regular.

In a commutative von Neumann regular ring, for each element x there is a unique element y such that xyx=x and yxy=y, so there is a canonical way to choose the "weak inverse" of x. The following statements are equivalent for the commutative ring R:

Also, the following are equivalent: for a commutative ring A

Every semisimple ring is von Neumann regular, and a left (or right) Noetherian von Neumann regular ring is semisimple. Every von Neumann regular ring has Jacobson radical {0} and is thus semiprimitive (also called "Jacobson semi-simple").

Generalizing the above example, suppose S is some ring and M is an S-module such that every submodule of M is a direct summand of M (such modules M are called semisimple). Then the endomorphism ring EndS(M) is von Neumann regular. In particular, every semisimple ring is von Neumann regular.

Generalizations and specializations

Special types of von Neumann regular rings include unit regular rings and strongly von Neumann regular rings and rank rings.

A ring R is called unit regular if for every a in R, there is a unit u in R such that a = aua. Every semisimple ring is unit regular, and unit regular rings are directly finite rings. An ordinary von Neumann regular ring need not be directly finite.

A ring R is called strongly von Neumann regular if for every a in R, there is some x in R with a = aax. The condition is left-right symmetric. Strongly von Neumann regular rings are unit regular. Every strongly von Neumann regular ring is a subdirect product of division rings. In some sense, this more closely mimics the properties of commutative von Neumann regular rings, which are subdirect products of fields. Of course for commutative rings, von Neumann regular and strongly von Neumann regular are equivalent. In general, the following are equivalent for a ring R:

Generalizations of von Neumann regular rings include π-regular rings, left/right semihereditary rings, left/right nonsingular rings and semiprimitive rings.

See also

References

  1. 1 2 3 Kaplansky (1972) p.110
  2. Kaplansky (1972) p.112
  3. Michler, G.O.; Villamayor, O.E. (April 1973). "On rings whose simple modules are injective". Journal of Algebra. 25 (1): 185–201. doi:10.1016/0021-8693(73)90088-4. Retrieved 10 February 2017.

Further reading

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