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Global dipole symmetry, compact Lifshitz theory, tensor gauge theory, and fractons

Pranay Gorantla, Ho Tat Lam, Nathan Seiberg, Shu-Heng Shao

2022Physical review. B./Physical review. B109 citationsDOIOpen Access PDF

Abstract

We study field theories with global dipole symmetries and gauge dipole symmetries. The famous Lifshitz theory is an example of a theory with a global dipole symmetry. We study in detail its $1+1\mathrm{D}$ version with a compact field. When this global symmetry is promoted to a $U(1)$ dipole gauge symmetry, the corresponding gauge field is a tensor gauge field. This theory is known to lead to fractons. To resolve various subtleties in the precise meaning of these global or gauge symmetries, we place these $1+1\mathrm{D}$ theories on a lattice and then take the continuum limit. Interestingly, the continuum limit is not unique. Different limits lead to different continuum theories, whose operators, defects, global symmetries, etc., are different. We also consider a lattice gauge theory with a ${\mathbb{Z}}_{N}$ dipole gauge group. Surprisingly, several physical observables, such as the ground state degeneracy and the mobility of defects, depend sensitively on the number of sites in the lattice. Our analysis forces us to think carefully about global symmetries that do not act on the standard Hilbert space of the theory, but only on the Hilbert space in the presence of defects. We refer to them as timelike global symmetries and discuss them in detail. These timelike global symmetries allow us to phrase the mobility restrictions of defects (including those of fractons) as a consequence of a global symmetry.

Topics & Concepts

PhysicsGauge theoryGauge symmetryGlobal symmetryHomogeneous spaceTheoretical physicsHamiltonian lattice gauge theoryIntroduction to gauge theorySupersymmetric gauge theoryLattice gauge theoryQuantum mechanicsMathematical physicsMathematicsSpontaneous symmetry breakingSymmetry breakingGeometryQuantum many-body systemsPhysics of Superconductivity and MagnetismTheoretical and Computational Physics