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Modular Hamiltonian and modular flow of massless fermions on a cylinder

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arxiv 2406.19360 v1 pith:MH6MARCN submitted 2024-06-27 math-ph hep-thmath.MP

Modular Hamiltonian and modular flow of massless fermions on a cylinder

classification math-ph hep-thmath.MP
keywords modularstategroundcaseflowperiodicantiperiodichamiltonian
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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We determine explicitly the modular flow and the modular Hamiltonian for massless free fermions in diamonds on a cylinder in 1+1 dimensions. We consider both periodic and antiperiodic boundary conditions, the ground state in the antiperiodic case and the most general family of quasi-free zero-energy ground states in the periodic case, which depend on four parameters and are generally mixed. While for the antiperiodic ground state and one periodic ground state (the maximally mixed zero-temperature state) the modular data is known, our results for the generic ground state in the periodic case are completely new. We find that generically both the modular flow and the modular Hamiltonian are non-local, and we show that in the parametric limit where the state becomes pure the modular data becomes local. Moreover, even in the local case the modular flow generically mixes the two chiralities. This kind of behavior has not been observed previously.

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Cited by 2 Pith papers

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  2. Numerical approach to the modular operator for fermionic systems

    math-ph 2026-05 unverdicted novelty 6.0

    A position-space discretization on a cylinder approximates the modular operator for one and two double cones in the 1+1D massive Majorana field, showing nontrivial mass dependence and reduced bilocal terms at higher masses.