Euclidean E-models are constructed by setting E squared equal to minus the identity on Drinfeld doubles, yielding a separate formalism for Euclidean Poisson-Lie T-duality, integrability criteria, and one-loop renormalization illustrated by the bi-Yang-Baxter deformation.
Renormalization of Lorentz non-invariant actions and manifest T-duality
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abstract
We study general two-dimensional sigma-models which do not possess manifest Lorentz invariance. We show how demanding that Lorentz invariance is recovered as an emergent on-shell symmetry constrains these sigma-models. The resulting actions have an underlying group-theoretic structure and resemble Poisson-Lie T-duality invariant actions. We consider the one-loop renormalization of these models and show that the quantum Lorentz anomaly is absent. We calculate the running of the couplings in general and show, with certain non-trivial examples, that this agrees with that of the T-dual models obtained classically from the duality invariant action. Hence, in these cases solving constraints before and after quantization are commuting operations.
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hep-th 1years
2026 1verdicts
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Euclidean E-models
Euclidean E-models are constructed by setting E squared equal to minus the identity on Drinfeld doubles, yielding a separate formalism for Euclidean Poisson-Lie T-duality, integrability criteria, and one-loop renormalization illustrated by the bi-Yang-Baxter deformation.