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Uniformly hyperfinite algebra

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In mathematics, particularly in the theory of C*-algebras, a uniformly hyperfinite, or UHF, algebra is a C*-algebra that can be written as the closure, in the norm topology, of an increasing union of finite-dimensional full matrix algebras.

Definition

A UHF C*-algebra is the direct limit of an inductive system {An, φn} where each An is a finite-dimensional full matrix algebra and each φn : AnAn+1 is a unital embedding. Suppressing the connecting maps, one can write

A = n A n ¯ . {\displaystyle A={\overline {\cup _{n}A_{n}}}.}

Classification

If

A n M k n ( C ) , {\displaystyle A_{n}\simeq M_{k_{n}}(\mathbb {C} ),}

then rkn = kn + 1 for some integer r and

ϕ n ( a ) = a I r , {\displaystyle \phi _{n}(a)=a\otimes I_{r},}

where Ir is the identity in the r × r matrices. The sequence ...kn|kn + 1|kn + 2... determines a formal product

δ ( A ) = p p t p {\displaystyle \delta (A)=\prod _{p}p^{t_{p}}}

where each p is prime and tp = sup {m   |   p divides kn for some n}, possibly zero or infinite. The formal product δ(A) is said to be the supernatural number corresponding to A. Glimm showed that the supernatural number is a complete invariant of UHF C*-algebras. In particular, there are uncountably many isomorphism classes of UHF C*-algebras.

If δ(A) is finite, then A is the full matrix algebra Mδ(A). A UHF algebra is said to be of infinite type if each tp in δ(A) is 0 or ∞.

In the language of K-theory, each supernatural number

δ ( A ) = p p t p {\displaystyle \delta (A)=\prod _{p}p^{t_{p}}}

specifies an additive subgroup of Q that is the rational numbers of the type n/m where m formally divides δ(A). This group is the K0 group of A.

CAR algebra

One example of a UHF C*-algebra is the CAR algebra. It is defined as follows: let H be a separable complex Hilbert space H with orthonormal basis fn and L(H) the bounded operators on H, consider a linear map

α : H L ( H ) {\displaystyle \alpha :H\rightarrow L(H)}

with the property that

{ α ( f n ) , α ( f m ) } = 0 and α ( f n ) α ( f m ) + α ( f m ) α ( f n ) = f m , f n I . {\displaystyle \{\alpha (f_{n}),\alpha (f_{m})\}=0\quad {\mbox{and}}\quad \alpha (f_{n})^{*}\alpha (f_{m})+\alpha (f_{m})\alpha (f_{n})^{*}=\langle f_{m},f_{n}\rangle I.}

The CAR algebra is the C*-algebra generated by

{ α ( f n ) } . {\displaystyle \{\alpha (f_{n})\}\;.}

The embedding

C ( α ( f 1 ) , , α ( f n ) ) C ( α ( f 1 ) , , α ( f n + 1 ) ) {\displaystyle C^{*}(\alpha (f_{1}),\cdots ,\alpha (f_{n}))\hookrightarrow C^{*}(\alpha (f_{1}),\cdots ,\alpha (f_{n+1}))}

can be identified with the multiplicity 2 embedding

M 2 n M 2 n + 1 . {\displaystyle M_{2^{n}}\hookrightarrow M_{2^{n+1}}.}

Therefore, the CAR algebra has supernatural number 2. This identification also yields that its K0 group is the dyadic rationals.

References

  1. ^ Rørdam, M.; Larsen, F.; Laustsen, N.J. (2000). An Introduction to K-Theory for C*-Algebras. Cambridge: Cambridge University Press. ISBN 0521789443.
  2. Glimm, James G. (1 February 1960). "On a certain class of operator algebras" (PDF). Transactions of the American Mathematical Society. 95 (2): 318–340. doi:10.1090/S0002-9947-1960-0112057-5. Retrieved 2 March 2013.
  3. Davidson, Kenneth (1997). C*-Algebras by Example. Fields Institute. pp. 166, 218–219, 234. ISBN 0-8218-0599-1.
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