Abstract
We recast the action of pure gravity into a form that is invariant under a twofold Lorentz symmetry. To derive this representation, we construct a general parameterization of all theories equivalent to the Einstein-Hilbert action up to a local field redefinition and gauge fixing. We then exploit this freedom to eliminate all interactions except those exhibiting two sets of independently contracted Lorentz indices. The resulting action is local, remarkably simple, and naturally expressed in a field basis analogous to the exponential parameterization of the nonlinear sigma model. The space of twofold Lorentz invariant field redefinitions then generates an infinite class of equivalent representations. By construction, all off-shell Feynman diagrams are twofold Lorentz invariant while all on-shell tree amplitudes are automatically twofold gauge invariant. We extend our results to curved spacetime and calculate the analogue of the Einstein equations. While these twofold invariances are hidden in the canonical approach of graviton perturbation theory, they are naturally expected given the double copy relations for scattering amplitudes in gauge theory and gravity.
Highlights
We have presented a simple representation of the EH action that manifests index factorization and in turn twofold Lorentz symmetry
We have described a systematic search for a pure gravity action exhibiting the twofold Lorentz symmetry suggested by the double copy relations
This action extends to an infinite family of actions related by twofold Lorentz invariant field redefinitions
Summary
We define the space of local actions equivalent to the EH action modulo field redefinitions and gauge fixing. The EH action can be recast into a form that manifests index factorization and is compatible with twofold Lorentz. We will study graviton perturbation theory as an expansion about flat spacetime in Cartesian coordinates, ηab = diag(−1, 1, .
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