Two-loop scale-invariant scalar potential and quantum effective operators

Abstract

Spontaneous breaking of quantum scale invariance may provide a solution to the hierarchy and cosmological constant problems. In a scale-invariant regularization, we compute the two-loop potential of a higgs-like scalar φ in theories in which scale symmetry is broken only spontaneously by the dilaton (σ). Its vev σ generates the DR subtraction scale (μσ), which avoids the explicit scale symmetry breaking by traditional regularizations (where μ=fixed scale). The two-loop potential contains effective operators of non-polynomial nature as well as new corrections, beyond those obtained with explicit breaking (μ=fixed scale). These operators have the form: φ6/σ2, φ8/σ4, etc, which generate an infinite series of higher dimensional polynomial operators upon expansion about σ φ, where such hierarchy is arranged by one initial, classical tuning. These operators emerge at the quantum level from evanescent interactions (ε) between σ and φ that vanish in d=4 but are demanded by classical scale invariance in d=4-2ε. The Callan-Symanzik equation of the two-loop potential is respected and the two-loop beta functions of the couplings differ from those of the same theory regularized with μ=fixed scale. Therefore the running of the couplings enables one to distinguish between spontaneous and explicit scale symmetry breaking.