# On a self-dual phase space for 3+1 lattice Yang-Mills theory

**Authors:** Aldo Riello

arXiv: 1706.07811 · 2018-01-10

## TL;DR

This paper introduces a self-dual deformation of the classical phase space in lattice Yang-Mills theory, enhancing symmetry and geometric interpretation, with implications for quantization and topological field theories in 3+1 dimensions.

## Contribution

It presents a novel self-dual phase space construction for lattice Yang-Mills theory using quasi-Hamiltonian spaces, linking electric and magnetic fluxes with a geometric moduli space.

## Key findings

- Enhanced self-duality in 3+1 dimensions
- Connection to moduli space of non-commutative flat connections
- Implications for quantization and topological field theories

## Abstract

I propose a self-dual deformation of the classical phase space of lattice Yang--Mills theory, in which both the electric and magnetic fluxes take value in the gauge Lie group. A local construction of the deformed phase space requires the machinery of "quasi-Hamiltonian spaces" by Alekseev et al., which is here reviewed. The results is a full-fledged finite-dimensional and gauge-invariant phase space, whose self-duality properties are largely enhanced in (3+1) spacetime dimensions. This enhancement is due to a correspondence with the moduli space of an auxiliary non-commutative flat connection living on a Riemann surface defined from the lattice itself, which in turn equips the duality between electric and magnetic fluxes with a neat geometrical interpretation in terms of a Heegaard splitting of the space manifold. Finally, I discuss the consequences of the proposed deformation on the quantization of the phase space, its quantum gravitational interpretation, as well as its relevance for the construction of (3+1) dimensional topological field theories with defects.

## Full text

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## Figures

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## References

67 references — full list in the complete paper: https://tomesphere.com/paper/1706.07811/full.md

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Source: https://tomesphere.com/paper/1706.07811