Tuning supersymmetric models at the LHC: A comparative analysis at two-loop level

Abstract

We provide a comparative study of the fine tuning amount (Delta) at the two-loop leading log level in supersymmetric models commonly used in SUSY searches at the LHC. These are the constrained MSSM (CMSSM), non-universal Higgs masses models (NUHM1, NUHM2), non-universal gaugino masses model (NUGM) and GUT related gaugino masses models (NUGMd). Two definitions of the fine tuning are used, the first (Deltamax) measures maximal fine-tuning wrt individual parameters while the second (Deltaq) adds their contribution in "quadrature". As a direct result of two theoretical constraints (the EW minimum conditions), fine tuning (Deltaq) emerges as a suppressing factor (effective prior) of the averaged likelihood (under the priors), under the integral of the global probability of measuring the data (Bayesian evidence p(D)). For each model, there is little difference between Deltaq, Deltamax in the region allowed by the data, with similar behaviour as functions of the Higgs, gluino, stop mass or SUSY scale (msusy=(m t1 m t2)1/2) or dark matter and g-2 constraints. The analysis has the advantage that by replacing any of these mass scales or constraints by their latest bounds one easily infers for each model the value of Deltaq, Deltamax or vice versa. For all models, minimal fine tuning is achieved for Mhiggs near 115 GeV with a Deltaq≈ Deltamax≈ 10 to 100 depending on the model, and in the CMSSM this is actually a global minimum. Due to a strong (≈ exponential) dependence of Delta on Mhiggs, for a Higgs mass near 125 GeV, the above values of Deltaq≈ Deltamax increase to between 500 and 1000. Possible corrections to these values are briefly discussed.