Let L denote the bounded operators on a Hilbert spaceH, M ⊂ L be a von Neumann algebra, and M' the commutant of M. The center of M is Z = M' ∩ M =. The central carrier C of a projection E in M is defined as follows: The symbol ∧ denotes the lattice operation on the projections in Z: F1 ∧ F2 is the projection onto the closed subspace Ran ∩ Ran. The abelian algebraZ, being the intersection of two von Neumann algebras, is also a von Neumann algebra. Therefore, C lies in Z. If one thinks of M as a direct sum of its factors, then the central projections are the projections that are direct sums of identity operators of the factors. If E is confined to a single factor, then C is the identity operator in that factor. Informally, one would expectC to be the direct sum of identity operators I where I is in a factor and I · E ≠ 0.
The projection C can be described more explicitly. It can be shown that Ran C is the closed subspace generated by MRan. If N is a von Neumann algebra, and E a projection that does not necessarily belong to N and has range K = Ran. The smallest central projection in N that dominates E is precisely the projection onto the closed subspace generated by N' K. In symbols, if then Ran = . That ⊂ Ran follows from the definition of commutant. On the other hand, is invariant under every unitary U in N' . Therefore the projection onto lies in ' = N. Minimality of F' then yields Ran ⊂ . Now if E is a projection in M, applying the above to the von Neumann algebra Z gives
Related results
One can deduce some simple consequences from the above description. Suppose E and F are projections in a von Neumann algebra M. PropositionETF = 0 for all T in M if and only if C and C are orthogonal, i.e. C'C = 0. Proof: In turn, the following is true: Corollary Two projections E and F in a von Neumann algebra M contain two nonzero subprojections that are Murray-von Neumann equivalent if C'C ≠ 0. Proof: In particular, when M is a factor, then there exists a partial isometryU ∈ M such that UU* ≤ E and U*U ≤ F. Using this fact and a maximality argument, it can be deduced that the Murray-von Neumann partial order « on the family of projections in M becomes a total order if M is a factor. Proposition If M is a factor, and E, F ∈ M are projections, then either E « F or F « E. Proof: Without the assumption that M is a factor, we have: Proposition If M is a von Neumann algebra, and E, F ∈ M are projections, then there exists a central projection P ∈ Z such that either EP « FP and F « E. Proof:
