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On Higher Derivatives in 3D Gravity and Higher Spin Gauge Theories

Eric A. Bergshoeff, Olaf Hohm, Paul K. Townsend

Abstract

The general second-order massive field equations for arbitrary positive integer spin in three spacetime dimensions, and their "self-dual" limit to first-order equations, are shown to be equivalent to gauge-invariant higher-derivative field equations. We recover most known equivalences for spins 1 and 2, and find some new ones. In particular, we find a non-unitary massive 3D gravity theory with a 5th order term obtained by contraction of the Ricci and Cotton tensors; this term is part of an N=2 super-invariant that includes the "extended Chern-Simons" term of 3D electrodynamics. We also find a new unitary 6th order gauge theory for "self-dual" spin 3.

On Higher Derivatives in 3D Gravity and Higher Spin Gauge Theories

Abstract

The general second-order massive field equations for arbitrary positive integer spin in three spacetime dimensions, and their "self-dual" limit to first-order equations, are shown to be equivalent to gauge-invariant higher-derivative field equations. We recover most known equivalences for spins 1 and 2, and find some new ones. In particular, we find a non-unitary massive 3D gravity theory with a 5th order term obtained by contraction of the Ricci and Cotton tensors; this term is part of an N=2 super-invariant that includes the "extended Chern-Simons" term of 3D electrodynamics. We also find a new unitary 6th order gauge theory for "self-dual" spin 3.

Paper Structure

This paper contains 7 sections, 107 equations.

Table of Contents

  1. Introduction
  2. Higher-derivative 3D electrodynamics
  3. Higher-derivative 3D gravity
  4. Higher-derivative ${\cal N}=2$ supergravity
  5. Spin 3
  6. Canonical analysis
  7. Discussion