Abstract
We consider possible non-signaling composites of probabilistic models based on euclidean Jordan algebras (EJAs), satisfying some reasonable additional constraints motivated by the desire to construct dagger-compact categories of such models. We show that no such composite has the exceptional Jordan algebra as a direct summand, nor does any such composite exist if one factor has an exceptional summand, unless the other factor is a direct sum of one-dimensional Jordan algebras (representing essentially a classical system). Moreover, we show that any composite of simple, non-exceptional EJAs is a direct summand of their universal tensor product, sharply limiting the possibilities.These results warrant our focussing on concrete Jordan algebras of hermitian matrices, i.e., euclidean Jordan algebras with a preferred embedding in a complex matrix algebra. We show that these can be organized in a natural way as a symmetric monoidal category, albeit one that is not compact closed. We then construct a related category InvQM of embedded euclidean Jordan algebras, having fewer objects but more morphisms, that is not only compact closed but dagger-compact. This category unifies finite-dimensional real, complex and quaternionic mixed-state quantum mechanics, except that the composite of two complex quantum systems comes with an extra classical bit.Our notion of composite requires neither tomographic locality, nor preservation of purity under tensor product. The categories we construct include examples in which both of these conditions fail. {In such cases, the information capacity (the maximum number of mutually distinguishable states) of a composite is greater than the product of the capacities of its constituents.}
Highlights
Real Jordan algebras were first proposed as models of quantum systems by P.Jordan in 1933 [40]
Restricting attention further to Jordan algebras corresponding to real, complex and quaternionic quantum systems — equivalently, self-adjoint parts of real, complex and quaternionic matrix algebras — we identify two different monoidal sub-categories extending the category of finite-dimensional complex matrix algebras and complex and quaternionic quantum systems and processes (CP maps)
While we make no use of this result here, it is at the center of efforts to provide an operational motivation for euclidean Jordan algebras as models of physical systems, e.g., in [66, 15]
Summary
Real Jordan algebras were first proposed as models of quantum systems by P. From this it follows that no simple, nontrivial EJA has any composite with an exceptional EJA (Corollary 4.14), and that if A and B are simple, special EJAs, any composite of A and B must be an ideal — that is, a direct summand — in their universal tensor product (Theorem 4.15) These results warrant our focusing on special EJAs. Section 5 develops a canonical, and naturally associative, tensor product of embedded EJAs, that is, pairs (A, MA) where MA is a finite-dimensional complex ∗-algebra and A is a Jordan subalgebra of the self-adjoint part of MA. To avoid obstructing the flow of the main arguments, we have removed some technical details to a series of appendices
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