Nets of standard subspaces on Lie groups

Abstract

Let G be a Lie group with Lie algebra g, h ∈ g an element for which the derivation ad(h) defines a 3-grading of g and τG an involutive automorphism of G inducing on g the involution eπ i ad(h). We consider antiunitary representations U of the Lie group Gτ = G \e,τG\ for which the positive cone CU = \ x ∈ g : -i ∂ U(x) ≥ 0\ and h span g. To a real subspace E of distribution vectors invariant under exp(R h) and an open subset O ⊂eq G, we associate the real subspace HE(O) ⊂eq H, generated by the subspaces U()E, where ∈ C∞c(O,R) is a real-valued test function on O. Then HE(O) is dense in HE(G) for every non-empty open subset O ⊂eq G (Reeh--Schlider property). For the real standard subspace V ⊂eq H, for which JV = U(τG) is the modular conjugation and V-it/2π = U( th) is the modular group, we obtain sufficient conditions to be of the form HE(S) for an open subsemigroup S ⊂eq G. If g is semisimple with simple hermitian ideals of tube type, we verify these criteria and obtain nets of cyclic subspacs HE(O), O ⊂eq G, satisfying the Bisognano--Wichman property for some domains O. Our construction also yields such nets on simple Jordan space-times and compactly causal symmetric spaces of Cayley type. By second quantization, these nets lead to free quantum fields in the sense of Haag--Kastler on causal homogeneous spaces whose groups are generated by modular groups and conjugations.