English

Locality and Exceptional Points in Pseudo-Hermitian Physics

Quantum Physics 2023-06-08 v1 Mathematical Physics math.MP

Abstract

Pseudo-Hermitian operators generalize the concept of Hermiticity. This class of operators includes the quasi-Hermitian operators, which reformulate quantum theory while retaining real-valued measurement outcomes and unitary time evolution. This thesis is devoted to the study of locality in quasi-Hermitian theory, the symmetries and conserved quantities associated with non-Hermitian operators, and the perturbative features of pseudo-Hermitian matrices. In addition to the presented original research, scholars will appreciate the lengthy introduction to non-Hermitian physics. Local quasi-Hermitian observable algebras are examined. Expectation values of local quasi-Hermitian observables equal expectation values of local Hermitian observables. Thus, quasi-Hermitian theories do not increase the values of nonlocal games set by Hermitian theories. Furthermore, Bell's inequality violations in quasi-Hermitian theories never exceed the Tsirelson bound of Hermitian quantum theory. Exceptional points, which are branch points in the spectrum, are a perturbative feature unique to non-Hermitian operators. Cusp singularities of algebraic curves are related to higher-order exceptional points. To exemplify novelties of non-Hermiticity, one-dimensional lattice models with a pair of non-Hermitian defect potentials with balanced loss and gain, Δ±iγ\Delta \pm i \gamma, are explored. When the defects are nearest neighbour, the entire spectrum becomes complex when γ\gamma is tuned past a second-order exceptional point. When the defects are at the edges of the chain and the hopping amplitudes are 2-periodic, as in the Su-Schrieffer-Heeger chain, the PT\mathcal{PT}-phase transition is dictated by the topological phase. Chiral symmetry and representation theory are used to derive large classes of pseudo-Hermitian operators with closed-form intertwining operators.

Keywords

Cite

@article{arxiv.2306.04044,
  title  = {Locality and Exceptional Points in Pseudo-Hermitian Physics},
  author = {Jacob L. Barnett},
  journal= {arXiv preprint arXiv:2306.04044},
  year   = {2023}
}

Comments

257 pages, 23 figures

R2 v1 2026-06-28T10:58:18.492Z