Noncommutative Dynamics of Random Operators

Abstract

We continue our program of unifying general relativity and quantum mechanics in terms of a noncommutative algebra A on a transformation groupoid = E × G where E is the total space of a principal fibre bundle over spacetime, and G a suitable group acting on . We show that every a ∈ A defines a random operator, and we study the dynamics of such operators. In the noncommutative regime, there is no usual time but, on the strength of the Tomita-Takesaki theorem, there exists a one-parameter group of automorphisms of the algebra A which can be used to define a state dependent dynamics; i.e., the pair ( A, φ), where φ is a state on A, is a ``dynamic object''. Only if certain additional conditions are satisfied, the Connes-Nikodym-Radon theorem can be applied and the dependence on φ disappears. In these cases, the usual unitary quantum mechanical evolution is recovered. We also notice that the same pair ( A, φ) defines the so-called free probability calculus, as developed by Voiculescu and others, with the state φ playing the role of the noncommutative probability measure. This shows that in the noncommutative regime dynamics and probability are unified. This also explains probabilistic properties of the usual quantum mechanics.

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