Vacuum Stability of Standard Model^{++}

TL;DR

This paper investigates the vacuum stability of an extended Standard Model (SM++) with an added scalar singlet and U(1) gauge symmetry, showing conditions under which the vacuum remains stable up to the Planck scale.

Contribution

The study derives one-loop renormalization group equations for SM++ and explores stability bounds, identifying parameter ranges that ensure absolute vacuum stability up to the Planck scale.

Findings

Vacuum stability depends on scalar mixing angle and scalar mass.

Stable vacuum up to the Planck scale is possible for specific mixing angles and scalar masses.

Results are largely independent of certain TeV-scale parameters.

Abstract

The latest results of the ATLAS and CMS experiments point to a preferred narrow Higgs mass range (m_h \simeq 124 - 126 GeV) in which the effective potential of the Standard Model (SM) develops a vacuum instability at a scale 10^{9} -10^{11} GeV, with the precise scale depending on the precise value of the top quark mass and the strong coupling constant. Motivated by this experimental situation, we present here a detailed investigation about the stability of the SM^{++} vacuum, which is characterized by a simple extension of the SM obtained by adding to the scalar sector a complex SU(2) singlet that has the quantum numbers of the right-handed neutrino, H", and to the gauge sector an U(1) that is broken by the vacuum expectation value of H". We derive the complete set of renormalization group equations at one loop. We then pursue a numerical study of the system to determine the triviality and vacuum stability bounds, using a scan of 10^4 random set of points to fix the initial conditions. We show that, if there is no mixing in the scalar sector, the top Yukawa coupling drives the quartic Higgs coupling to negative values in the ultraviolet and, as for the SM, the effective potential develops an instability below the Planck scale. However, for a mixing angle -0.35 \alt \alpha \alt -0.02 or 0.01 \alt \alpha \alt 0.35, with the new scalar mass in the range 500 GeV \alt m_{h"} \alt 8 TeV, the SM^{++} ground state can be absolutely stable up to the Planck scale. These results are largely independent of TeV-scale free parameters in the model: the mass of the non-anomalous U(1) gauge boson and its branching fractions.