Two-Higgs-doublet model

Currently, experimental data seems to match well with the predictions of the Standard Model (SM). However, there is a widespread belief that due to many unanswered questions like dark matter, neutrino masses, the hierarchy problem, and the strong CP-problem, physics beyond the SM must exist. The Two-Higgs-doublet model (2HDM) is one of the simplest extensions of the SM.[1][2] 2HDM models are one of the natural choices for beyond-SM models containing two Higgs doublets instead of just one. There are also models with more than two Higgs doublets, for example three Higgs doublet models etc.[3]

The addition of the second Higgs doublet leads to a richer phenomenology as there are five physical scalar states viz., the CP even neutral Higgs bosons $h$ and $H$ (where $H$ is heavier than $h$ by convention), the CP odd pseudoscalar $A$ and two charged Higgs bosons $H^{\pm }$ . The discovered Higgs boson is measured to be CP even, so one can map either $h$ or $H$ with the observed Higgs. A special case occurs when $\cos(\beta -\alpha )\rightarrow 0$ , the alignment limit, in which the lighter CP even Higgs boson $h$ has couplings exactly like the SM-Higgs boson.[4] In another limit such limit, where $\sin(\beta -\alpha )\rightarrow 0$ , the heavier CP even boson, i.e. $H$ is SM-like, leaving $h$ to be the lighter than the discovered Higgs.

Such a model can be described in terms of has six physical parameters: four Higgs masses ( $m_{h},m_{H},m_{A},m_{H^{\pm }}$ ), the ratio of the two vacuum expectation values ( $\tan \beta$ ) and the mixing angle ( $\alpha$ ) which diagonalizes the mass matrix of the neutral CP even Higgses. The SM uses only 2 parameters: the mass of the Higgs and its vacuum expectation value.

Classification

Two-Higgs-doublet models can introduce Flavor-changing neutral currents which have not been observed so far. The Glashow-Weinberg condition, requiring that each group of fermions (up-type quarks, down-type quarks and charged leptons) couples exactly to one of the two doublets, is sufficient to avoid the prediction of flavor-changing neutral currents.

Depending on which type of fermions couples to which doublet $\Phi$ , one can divide two-Higgs-doublet models into the following classes:[5][6]

Type	Description	up-type quarks couple to	down-type quarks couple to	charged leptons couple to	remarks
Type I	Fermiophobic	$\Phi _{2}$	$\Phi _{2}$	$\Phi _{2}$	charged fermions only couple to second doublet
Type II	MSSM-like	$\Phi _{2}$	$\Phi _{1}$	$\Phi _{1}$	up- and down-type quarks couple to separate doublets
X	Lepton-specific	$\Phi _{2}$	$\Phi _{2}$	$\Phi _{1}$
Y	Flipped	$\Phi _{2}$	$\Phi _{1}$	$\Phi _{2}$
Type III		$\Phi _{1},\Phi _{2}$	$\Phi _{1},\Phi _{2}$	$\Phi _{1},\Phi _{2}$	Flavor-changing neutral currents at tree level
Type FCNC-free		$\Phi _{1},\Phi _{2}$	$\Phi _{1},\Phi _{2}$	$\Phi _{1},\Phi _{2}$	By finding a matrix pair which can be diagonalized simultaneously. [7]

By convention, $\Phi _{2}$ is the doublet to which up-type quarks couple.

References

"Higgs Scalars and the Nonleptonic Weak Interactions," Christopher T. Hill, (1977); see pg. 100.
Gunion, J.; H. E. Haber; G. L. Kane; S. Dawson (1990). The Higgs Hunters Guide. Addison-Wesley.
Keus, Venus; King, Stephen F.; Moretti, Stefano (2014-01-13). "Three-Higgs-doublet models: symmetries, potentials and Higgs boson masses". Journal of High Energy Physics. 2014 (1): 52. arXiv:1310.8253. Bibcode:2014JHEP...01..052K. doi:10.1007/JHEP01(2014)052. ISSN 1029-8479.
Craig, N.; Galloway, J.; Thomas, S. (2013). "Searching for Signs of the Second Higgs Doublet". arXiv:1305.2424 [hep-ph].
Craig, N.; Thomas, S. (2012). "Exclusive Signals of an Extended Higgs Sector". Journal of High Energy Physics. 1211 (11): 083. arXiv:1207.4835. Bibcode:2012JHEP...11..083C. doi:10.1007/JHEP11(2012)083.
Branco, G. C.; Ferreira, P.M.; Lavoura, L.; Rebelo, M.N.; Sher, Marc; Silva, João P. (July 2012). "Theory and phenomenology of two-Higgs-doublet models". Physics Reports. Elsevier. 516 (1): 1–102. arXiv:1106.0034. Bibcode:2012PhR...516....1B. doi:10.1016/j.physrep.2012.02.002.CS1 maint: ref=harv (link)
Craig, Nathaniel; Galloway, Jamison; Thomas, Scott (2016). "CP-Violation in the Type-III Natural-Flavor-Conserving 2HDM". arXiv:1612.02891v3 [hep-ph].

This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.

[1] "Higgs Scalars and the Nonleptonic Weak Interactions," Christopher T. Hill, (1977); see pg. 100.

[2] Gunion, J.; H. E. Haber; G. L. Kane; S. Dawson (1990). The Higgs Hunters Guide. Addison-Wesley.

[3] Keus, Venus; King, Stephen F.; Moretti, Stefano (2014-01-13). "Three-Higgs-doublet models: symmetries, potentials and Higgs boson masses". Journal of High Energy Physics. 2014 (1): 52. arXiv:1310.8253. Bibcode:2014JHEP...01..052K. doi:10.1007/JHEP01(2014)052. ISSN 1029-8479.

[4] Craig, N.; Galloway, J.; Thomas, S. (2013). "Searching for Signs of the Second Higgs Doublet". arXiv:1305.2424 [hep-ph].

[5] Craig, N.; Thomas, S. (2012). "Exclusive Signals of an Extended Higgs Sector". Journal of High Energy Physics. 1211 (11): 083. arXiv:1207.4835. Bibcode:2012JHEP...11..083C. doi:10.1007/JHEP11(2012)083.

[6] Branco, G. C.; Ferreira, P.M.; Lavoura, L.; Rebelo, M.N.; Sher, Marc; Silva, João P. (July 2012). "Theory and phenomenology of two-Higgs-doublet models". Physics Reports. Elsevier. 516 (1): 1–102. arXiv:1106.0034. Bibcode:2012PhR...516....1B. doi:10.1016/j.physrep.2012.02.002.CS1 maint: ref=harv (link)

[7] Craig, Nathaniel; Galloway, Jamison; Thomas, Scott (2016). "CP-Violation in the Type-III Natural-Flavor-Conserving 2HDM". arXiv:1612.02891v3 [hep-ph].