Abstract
We explore the possibility that scale symmetry is a quantum symmetry that is broken only spontaneously and apply this idea to the Standard Model (SM). We compute the quantum corrections to the potential of the higgs field ($\phi$) in the classically scale invariant version of the SM ($m_\phi=0$ at tree level) extended by the dilaton ($\sigma$). The tree-level potential of $\phi$ and $\sigma$, dictated by scale invariance, may contain non-polynomial effective operators, e.g. $\phi^6/\sigma^2$, $\phi^8/\sigma^4$, $\phi^{10}/\sigma^6$, etc. The one-loop scalar potential is scale invariant, since the loop calculations manifestly preserve the scale symmetry, with the DR subtraction scale $\mu$ generated spontaneously by the dilaton vev $\mu\sim\langle\sigma\rangle$. The Callan-Symanzik equation of the potential is verified in the presence of the gauge, Yukawa and the non-polynomial operators. The couplings of the non-polynomial operators have non-zero beta functions that we can actually compute from the quantum potential. At the quantum level the higgs mass is protected by spontaneously broken scale symmetry, even though the theory is non-renormalizable. We compare the one-loop potential to its counterpart computed in the "traditional" DR scheme that breaks scale symmetry explicitly ($\mu=$constant) in the presence at the tree level of the non-polynomial operators.
Highlights
We explored the possibility that scale symmetry is a quantum symmetry of the standard model (SM) that is broken spontaneously
The vev hσi ≠ 0 breaks the scale symmetry spontaneously and dynamically generates a subtraction scale μ ∼ hσi that is necessary for quantum calculations
The classical scalar potential is dictated by the scale symmetry only and may contain nonpolynomial effective operators such as λ6φ6=σ2, λ8φ8=σ4, λ10φ10=σ6, λ12φ12=σ8, etc; these may always be Taylor expanded into a sum of infinitely many polynomial operators in fields fluctuations suppressed by powers of hσi, but in such a case, the manifest scale symmetry of the theory is lost
Summary
We explore the idea that scale symmetry is a quantum symmetry and study its implications for physics beyond the standard model (SM). Stable under quantum corrections, so mφ ∼ hφi ≪ hσi without tuning at the quantum level [4,8], and we verify this in our model at one loop This is expected to remain true to all orders in perturbation theory since scale symmetry is preserved by the regularization and is broken only spontaneously.. The couplings still run with momentum [6,7,8] since the vanishing of the beta functions is not a necessary condition for scale invariance Their oneloop running is identical to that in the theory with explicit scale symmetry breaking (μ 1⁄4 constant), but at two loops, they start to differ in theories with spontaneous vs explicit breaking [7,10]. It may still be possible to perform a scale-invariant regularization and examine such a scale-invariant theory at the quantum level
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