Enlarging the symmetry of pure R2 gravity, BRST invariance and its spontaneous breaking

Abstract

Pure R2 gravity was considered originally to possess only global scale symmetry. It was later shown to have the larger restricted Weyl symmetry where it is invariant under the Weyl transformation gμ 2(x)\, gμ when the conformal factor (x) obeys the harmonic condition (x)=0. Restricted Weyl symmetry has an analog in gauge theory. Under a gauge transformation Aμ Aμ + 1e∂μ f(x), the gauge-fixing term (∂μAμ)2 has a residual gauge symmetry when f=0. In this paper, we consider scenarios where the symmetry of pure R2 gravity can be enlarged even further. In one scenario, we add a massless scalar field to the pure R2 gravity action and show that the action becomes on-shell Weyl invariant when the equations of motion are obeyed. We then enlarge the symmetry to a BRST symmetry where no on-shell or restricted Weyl condition is required. The BRST transformations here are not associated with gauge transformations (such as diffeomorphisms) but with Weyl (local scale) transformations where the conformal factor consists of a product of Grassmann variables. BRST invariance in this context is a generalization of Weyl invariance that is valid in the presence of the Weyl-breaking R2 term. In contrast to the BRST invariance of gauge theories like QCD, it is not preserved after quantization since renormalization introduces a scale (leading to the well-known Weyl (conformal) anomaly). We show that the spontaneous breaking of the BRST symmetry yields an Einstein action; this still has a symmetry which is also anomalous. This is in accord with previous work that shows that there is conformal anomaly matching between the unbroken and broken phases when conformal symmetry is spontaneously broken.