A review of naturalness and dark matter prediction for the Higgs mass in MSSM and beyond

TL;DR

This review analyzes Higgs mass predictions in the MSSM and beyond, emphasizing naturalness and dark matter constraints, and discusses how new physics operators influence these predictions within the CMSSM framework.

Contribution

It provides a comprehensive review of Higgs mass predictions considering naturalness, dark matter, and effects of higher-dimensional operators beyond the MSSM.

Findings

Higgs mass predicted to be just above LEP2 bound at 115.9±2 GeV.

Higher Higgs masses (>121 GeV) require significant fine-tuning (Delta>100).

New physics operators can modify Higgs mass predictions by a few GeV.

Abstract

Within a two-loop leading-log approximation, we review the prediction for the lightest Higgs mass (m_h) in the framework of constrained MSSM (CMSSM), derived from the naturalness requirement of minimal fine-tuning (Delta) of the electroweak scale and dark matter consistency. As a result, the Higgs mass is predicted to be just above the LEP2 bound, m_h=115.9\pm 2 GeV, corresponding to a minimal Delta=17.8, value obtained from consistency with electroweak and WMAP (3\sigma) constraints, but without the LEP2 bound. Due to quantum corrections (largely QCD ones for m_h above LEP2 bound), Delta grows \approx exponentially on either side of the above value of m_h, which stresses the relevance of this prediction. A value m_h>121 (126) GeV cannot be accommodated within the CMSSM unless one accepts a fine-tuning cost worse than Delta>100 (1000), respectively. We review how the above prediction for m_h and Delta changes under the addition of new physics beyond the MSSM Higgs sector, parametrized by effective operators of dimensions d=5 and d=6. For d=5 operators, one can obtain values m_h\leq 130 GeV for Delta<10. The size of the supersymmetric correction that each individual operator of d=6 brings to the value of m_h for points with Delta<100, is found to be small, of few (<4) GeV for M=8 TeV, where M is the scale of new physics. This value decreases (increases) by approximately 1 GeV for a 1 TeV increase (decrease) of the scale M. The relation of these results to the Atlas/CMS supersymmetry exclusion limits is presented together with their impact for the CMSSM regions of lowest fine-tuning.