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Relative Entropy for Fermionic Quantum Field Theory

Mathematical Physics 2022-10-20 v1 High Energy Physics - Theory math.MP Quantum Physics

Abstract

We study the relative entropy, in the sense of Araki, for the representation of a self-dual CAR algebra ASDC(H,Γ)\mathfrak{A}_{SDC}(\mathcal{H},\Gamma). We notice, for a specific choice of fHf \in \mathcal{H}, that the associated element in ASDC(H,Γ)\mathfrak{A}_{SDC}(\mathcal{H},\Gamma) is unitary. As a consequence, we explicitly compute the relative entropy between a quasifree state over ASDC(H,Γ)\mathfrak{A}_{SDC}(\mathcal{H},\Gamma) and an excitation of it with respect to the abovely mentioned unitary element. The generality of the approach, allows us to consider H\mathcal{H} as the Hilbert space of solutions of the classical Dirac equation over globally hyperbolic spacetimes, making our result, a computation of relative entropy for a Fermionic Quantum Field Theory. Our result extends those of Longo and Casini et al. for the relative entropy between a quasifree state and a coherent excitation for a free Scalar Quantum Field Theory, to the case of fermions. As a first application, we computed such a relative entropy for a Majorana field on an ultrastatic spacetime.

Keywords

Cite

@article{arxiv.2210.10746,
  title  = {Relative Entropy for Fermionic Quantum Field Theory},
  author = {Stefano Galanda},
  journal= {arXiv preprint arXiv:2210.10746},
  year   = {2022}
}

Comments

Latex, 120 pages, 7 figures. Thesis accepted in partial fulfillment of the requirements for the Master in Mathematical Physics, University of Leipzig, with original results. Thesis supervisors: Dr. Albert Much and Prof. Rainer Verch. A journal publication with further results will be forthcoming

R2 v1 2026-06-28T04:01:11.219Z