Hyperfinite type II factor

Last updated April 08, 2019

In mathematics, there are up to isomorphism exactly two separably acting hyperfinite type II factors; one infinite and one finite. Murray and von Neumann proved that up to isomorphism there is a unique von Neumann algebra that is a factor of type II₁ and also hyperfinite; it is called the hyperfinite type II₁ factor. There are an uncountable number of other factors of type II₁. Connes proved that the infinite one is also unique.

Mathematics Field of study concerning quantity, patterns and change

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In mathematics, a von Neumann algebra or W*-algebra is a *-algebra of bounded operators on a Hilbert space that is closed in the weak operator topology and contains the identity operator. It is a special type of C*-algebra.

In mathematics, an isomorphism is a homomorphism or morphism that can be reversed by an inverse morphism. Two mathematical objects are isomorphic if an isomorphism exists between them. An automorphism is an isomorphism whose source and target coincide. The interest of isomorphisms lies in the fact that two isomorphic objects cannot be distinguished by using only the properties used to define morphisms; thus isomorphic objects may be considered the same as long as one considers only these properties and their consequences.

Constructions

The von Neumann group algebra of a discrete group with the infinite conjugacy class property is a factor of type II₁, and if the group is amenable and countable the factor is hyperfinite. There are many groups with these properties, as any locally finite group is amenable. For example, the von Neumann group algebra of the infinite symmetric group of all permutations of a countable infinite set that fix all but a finite number of elements gives the hyperfinite type II₁ factor.
The hyperfinite type II₁ factor also arises from the group-measure space construction for ergodic free measure-preserving actions of countable amenable groups on probability spaces.
The infinite tensor product of a countable number of factors of type I_n with respect to their tracial states is the hyperfinite type II₁ factor. When n=2, this is also sometimes called the Clifford algebra of an infinite separable Hilbert space.
If p is any non-zero finite projection in a hyperfinite von Neumann algebra A of type II, then pAp is the hyperfinite type II₁ factor. Equivalently the fundamental group of A is the group of positive real numbers. This can often be hard to see directly. It is, however, obvious when A is the infinite tensor product of factors of type I_n, where n runs over all integers greater than 1 infinitely many times: just take p equivalent to an infinite tensor product of projections p_n on which the tracial state is either $1$ or $1-1/n$ .

In mathematics, a group is said to have the infinite conjugacy class property, or to be an icc group, if the conjugacy class of every group element but the identity is infinite.

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Properties

The hyperfinite II₁ factor R is the unique smallest infinite dimensional factor in the following sense: it is contained in any other infinite dimensional factor, and any infinite dimensional factor contained in R is isomorphic to R.

The outer automorphism group of R is an infinite simple group with countable many conjugacy classes, indexed by pairs consisting of a positive integer p and a complex pth root of 1.

The projections of the hyperfinite II₁ factor form a continuous geometry.

In mathematics, continuous geometry is an analogue of complex projective geometry introduced by von Neumann, where instead of the dimension of a subspace being in a discrete set 0, 1, ..., n, it can be an element of the unit interval [0,1]. Von Neumann was motivated by his discovery of von Neumann algebras with a dimension function taking a continuous range of dimensions, and the first example of a continuous geometry other than projective space was the projections of the hyperfinite type II factor.

The infinite hyperfinite type II factor

While there are other factors of type II_∞, there is a unique hyperfinite one, up to isomorphism. It consists of those infinite square matrices with entries in the hyperfinite type II₁ factor that define bounded operators.

In functional analysis, a bounded linear operator is a linear transformation L between normed vector spaces X and Y for which the ratio of the norm of L(v) to that of v is bounded above by the same number, over all non-zero vectors v in X. In other words, there exists some $such that for all v in X$

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References

A. Connes, Classification of Injective Factors The Annals of Mathematics 2nd Ser., Vol. 104, No. 1 (Jul., 1976), pp. 73–115
F.J. Murray, J. von Neumann, On rings of operators IV Ann. of Math. (2), 44 (1943) pp. 716–808. This shows that all approximately finite factors of type II₁ are isomorphic.

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