Lorentz-violating pseudovectors in effective field theories for quantum gravity

TL;DR

This paper explores Lorentz-violating terms in effective field theories for quantum gravity, focusing on pseudovector backgrounds, and derives bounds on these violations from cosmological and particle physics considerations.

Contribution

It introduces a criterion to select Lorentz-violating terms with pseudovectors and analyzes their implications across matter, gauge, and gravitational sectors.

Findings

Some gauge sector coefficients vanish at one loop.

Bounds on Lorentz violation in the Higgs sector are proposed.

New gravitational bounds are derived from cosmological models.

Abstract

Effective field theories which describe the coupling between gravity and matter fields have recently been extended to include terms with operators of non-minimal mass dimension. These terms preserve the usual gauge symmetries but may violate local Lorentz and diffeomorphism invariance. The number of possible terms in the field theory explodes once one allows for non-minimal operators, with no criterion to choose between them. We suggest as such a criterion to focus on terms which violate Lorentz invariance via a (pseudo)vector background field, leaving a number of possible terms in the Higgs, gauge and gravitational sectors. Further study of these terms is motivated by the proposed correspondence between the general effective theory for Lorentz violation and emergent Lorentz symmetry in condensed-matter systems, which is mostly unexplored for higher mass dimension operators and couplings to gauge fields and gravity. We suggest bounds in the Higgs sector and we show that some of the coefficients in the gauge sector vanish at one loop, whereas others have bounds which are comparable with those suggested by Kosteleck\'y and Li for coefficients in Lorentz-violating QCD and QED coupled to quarks. We also find new bounds in the gravitational sector by considering Robertson-Walker cosmology. Finally, we discuss the special case where only diffeomorphism invariance is spontaneously broken and explain why it does not allow for non-trivial Nambu-Goldstone modes.