2002
DOI: 10.1007/s000230200001
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Adiabatic Vacuum States on General Spacetime Manifolds: Definition, Construction, and Physical Properties

Abstract: Adiabatic vacuum states are a well-known class of physical states for linear quantum fields on Robertson-Walker spacetimes. We extend the definition of adiabatic vacua to general spacetime manifolds by using the notion of the Sobolev wavefront set. This definition is also applicable to interacting field theories. Hadamard states form a special subclass of the adiabatic vacua. We analyze physical properties of adiabatic vacuum representations of the Klein-Gordon field on globally hyperbolic spacetime manifolds … Show more

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Cited by 117 publications
(170 citation statements)
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“…Existence of a large class of Hadamard state on any globally hyperbolic spacetime can be established by a deformation argument [39] combined with microlocal techniques, or by methods from the theory of pseudo-differential operators [40,60].…”
Section: Formulation Of Linear Qftcs Via the Algebraic Approach (Withmentioning
confidence: 99%
“…Existence of a large class of Hadamard state on any globally hyperbolic spacetime can be established by a deformation argument [39] combined with microlocal techniques, or by methods from the theory of pseudo-differential operators [40,60].…”
Section: Formulation Of Linear Qftcs Via the Algebraic Approach (Withmentioning
confidence: 99%
“…We conclude that the real linear scalar field obeys a QEI with respect to the class of weights delineated by (3) and the class of Hadamard states. The same argument would apply to a suitable class of adiabatic states [32] in which one replaces the smooth wave-front set by a wave-front set modulo Sobolev regularity. Note that this QEI applies to the normal ordered stress-energy tensor, rather than the renormalised tensor.…”
Section: From Microscopic To Mesoscopicmentioning
confidence: 99%
“…(80) and (83) are correct due to the particular properties of the Fourier integral operators E + and E − . For the precise proof we refer to Lemma 5.6 in [2], but the essential idea is that even when P is only in…”
Section: E1 Addendum To Theorem 312mentioning
confidence: 99%
“…A similar argument justifies Eq. (82) (see the proof of Lemma 5.6 in [2], here the additional assumption enters that Q has a real-valued principal symbol). For the same reasons the operators Q in the proof of Theorem 3.18, Q n in Eq.…”
Section: E1 Addendum To Theorem 312mentioning
confidence: 99%
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