Abstract
We explore the possibility that the discrepancy in the observed anomalous magnetic moment of the muon Δaμ and the predicted relic abundance of Dark Matter by Planck data, can be explained in a lepto-philic 2-HDM augmented by a real SM singlet scalar of mass ∼ 10–80 GeV. We constrain the model from the observed Higgs Decay width at LHC, LEP searches for low mass exotic scalars and anomalous magnetic moment of an electron Δae. This constrained light singlet scalar serves as a portal for the fermionic Dark Matter, which contributes to the required relic density of the universe. A large region of model parameter space is found to be consistent with the present observations from the Direct and Indirect DM detection experiments.
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M. Garny, A. Ibarra, M. Pato and S. Vogl, Internal bremsstrahlung signatures in light of direct dark matter searches, JCAP12 (2013) 046 [arXiv:1306.6342] [INSPIRE].
J. Goodman et al., Constraints on light Majorana dark matter from colliders, Phys. Lett.B 695 (2011) 185 [arXiv:1005.1286] [INSPIRE].
J. Hisano, K. Ishiwata and N. Nagata, Direct detection of dark matter degenerate with colored particles in mass, Phys. Lett.B 706 (2011) 208 [arXiv:1110.3719] [INSPIRE].
M. Garny, A. Ibarra, M. Pato and S. Vogl, Closing in on mass-degenerate dark matter scenarios with antiprotons and direct detection, JCAP11 (2012) 017 [arXiv:1207.1431] [INSPIRE].
Fermi-LAT collaboration, Dark matter constraints from observations of 25 Milky Way satellite galaxies with the Fermi Large Area Telescope, Phys. Rev.D 89 (2014) 042001 [arXiv:1310.0828] [INSPIRE].
A. Dedes and H.E. Haber, Can the Higgs sector contribute significantly to the muon anomalous magnetic moment?, JHEP05 (2001) 006 [hep-ph/0102297] [INSPIRE].
T. Abe, R. Sato and K. Yagyu, Lepton-specific two Higgs doublet model as a solution of muon g − 2 anomaly, JHEP07 (2015) 064 [arXiv:1504.07059] [INSPIRE].
E.J. Chun, Z. Kang, M. Takeuchi and Y.-L.S. Tsai, LHC τ -rich tests of lepton-specific 2HDM for (g − 2)μ, JHEP11 (2015) 099 [arXiv:1507.08067] [INSPIRE].
C.-Y. Chen, H. Davoudiasl, W.J. Marciano and C. Zhang, Implications of a light “dark Higgs” solution to the g μ − 2 discrepancy, Phys. Rev.D 93 (2016) 035006 [arXiv:1511.04715] [INSPIRE].
http://pdg.lbl.gov/2019/reviews/rpp2018-rev-g-2-muon-anom-mag-moment.pdf.
K. Hagiwara et al., (g − 2)μand α(M Z) re-evaluated using new precise data, J. Phys.G 38 (2011) 085003 [arXiv:1105.3149] [INSPIRE].
B. Batell et al., Muon anomalous magnetic moment through the leptonic Higgs portal, Phys. Rev.D 95 (2017) 075003 [arXiv:1606.04943] [INSPIRE].
C. Bird, P. Jackson, R.V. Kowalewski and M. Pospelov, Search for dark matter in b → s transitions with missing energy, Phys. Rev. Lett.93 (2004) 201803 [hep-ph/0401195] [INSPIRE].
D. O’Connell, M.J. Ramsey-Musolf and M.B. Wise, Minimal extension of the standard model scalar sector, Phys. Rev.D 75 (2007) 037701 [hep-ph/0611014] [INSPIRE].
B. Batell, M. Pospelov and A. Ritz, Multi-lepton signatures of a hidden sector in rare B decays, Phys. Rev.D 83 (2011) 054005 [arXiv:0911.4938] [INSPIRE].
G. Krnjaic, Probing light thermal dark-matter with a Higgs portal mediator, Phys. Rev.D 94 (2016) 073009 [arXiv:1512.04119] [INSPIRE].
BaBar collaboration, Search for a muonic dark force at BABAR, Phys. Rev.D 94 (2016) 011102 [arXiv:1606.03501] [INSPIRE].
M. Battaglieri et al., The heavy photon search test detector, Nucl. Instrum. Meth.A 777 (2015) 91 [arXiv:1406.6115] [INSPIRE].
O. Lebedev, W. Loinaz and T. Takeuchi, Constraints on two Higgs doublet models at large tan β from W and Z decays, Phys. Rev.D 62 (2000) 055014 [hep-ph/0002106] [INSPIRE].
P. Agrawal, Z. Chacko and C.B. Verhaaren, Leptophilic dark matter and the anomalous magnetic moment of the muon, JHEP08 (2014) 147 [arXiv:1402.7369] [INSPIRE].
ALEPH, DELPHI, L3, OPAL, LEP Electroweak collaboration, Electroweak measurements in electron-positron collisions at W-boson-pair energies at LEP, Phys. Rept.532 (2013) 119 [arXiv:1302.3415] [INSPIRE].
ATLAS collaboration, Study of (W/Z)H production and Higgs boson couplings using H →WW ∗decays with the ATLAS detector,JHEP08(2015) 137 [arXiv:1506.06641] [INSPIRE].
http://pdg.lbl.gov/2019/reviews/rpp2018-rev-higgs-boson.pdf.
ATLAS collaboration, Search for charged Higgs bosons in the H ± → tb decay channel in pp collisions at \( \sqrt{S} \) = 8 TeV using the ATLAS detector, JHEP03 (2016) 127 [arXiv:1512.03704] [INSPIRE].
V. Ilisie, New Barr-Zee contributions to (g − 2)μin two-Higgs-doublet models, JHEP04 (2015) 077 [arXiv:1502.04199] [INSPIRE].
DELPHI collaboration, Searches for neutral Higgs bosons in extended models, Eur. Phys. J.C 38 (2004) 1 [hep-ex/0410017] [INSPIRE].
CMS collaboration, Search for Higgs boson off-shell production in proton-proton collisions at 7 and 8 TeV and derivation of constraints on its total decay width, JHEP09 (2016) 051 [arXiv:1605.02329] [INSPIRE].
CMS collaboration, Limits on the Higgs boson lifetime and width from its decay to four charged leptons, Phys. Rev.D 92 (2015) 072010 [arXiv:1507.06656] [INSPIRE].
ATLAS collaboration, Constraints on the off-shell Higgs boson signal strength in the high-mass ZZ and W W final states with the ATLAS detector, Eur. Phys. J.C 75 (2015) 335 [arXiv:1503.01060] [INSPIRE].
Heavy Flavor Averaging Group (HFAG) collaboration, Averages of b-hadron, c-hadron and τ -lepton properties as of summer 2014, arXiv:1412.7515 [INSPIRE].
M. Krawczyk and D. Temes, 2HDM(II) radiative corrections in leptonic tau decays, Eur. Phys. J.C 44 (2005) 435 [hep-ph/0410248] [INSPIRE].
M.E. Peskin and T. Takeuchi, A New constraint on a strongly interacting Higgs sector, Phys. Rev. Lett.65 (1990) 964 [INSPIRE].
M.E. Peskin and T. Takeuchi, Estimation of oblique electroweak corrections, Phys. Rev.D 46 (1992) 381 [INSPIRE].
G. Funk, D. O’Neil and R.M. Winters, What the oblique parameters S, T and U and their extensions reveal about the 2HDM: a numerical analysis, Int. J. Mod. Phys.A 27 (2012) 1250021 [arXiv:1110.3812] [INSPIRE].
Planck collaboration, Planck 2015 results. XIII. Cosmological parameters, Astron. Astrophys.594 (2016) A13 [arXiv:1502.01589] [INSPIRE].
WMAP Science Team collaboration, Results from the Wilkinson Microwave Anisotropy Probe, PTEP2014 (2014) 06B102 [arXiv:1404.5415] [INSPIRE].
F. Tanedo, Defense against the dark arts, http://www.physics.uci.edu/tanedo/files/notes/DMNotes.pdf.
F. Ambrogi et al., MadDM v.3.0: a comprehensive tool for dark matter studies, Phys. Dark Univ.24 (2019) 100249 [arXiv:1804.00044] [INSPIRE].
J. Alwall et al., The automated computation of tree-level and next-to-leading order differential cross sections and their matching to parton shower simulations, JHEP07 (2014) 079 [arXiv:1405.0301] [INSPIRE].
A. Alloul et al., FeynRules 2.0 — A complete toolbox for tree-level phenomenology, Comput. Phys. Commun.185 (2014) 2250 [arXiv:1310.1921] [INSPIRE].
J. Kopp, L. Michaels and J. Smirnov, Loopy constraints on leptophilic dark matter and internal Bremsstrahlung, JCAP04 (2014) 022 [arXiv:1401.6457] [INSPIRE].
J. Kopp, V. Niro, T. Schwetz and J. Zupan, DAMA/LIBRA and leptonically interacting Dark Matter, Phys. Rev.D 80 (2009) 083502 [arXiv:0907.3159] [INSPIRE].
F. D’Eramo, B.J. Kavanagh and P. Panci, Probing leptophilic dark sectors with hadronic processes, Phys. Lett.B 771 (2017) 339 [arXiv:1702.00016] [INSPIRE].
F. Bishara, J. Brod, B. Grinstein and J. Zupan, DirectDM: a tool for dark matter direct detection, arXiv:1708.02678 [INSPIRE].
M. Cirelli, E. Del Nobile and P. Panci, Tools for model-independent bounds in direct dark matter searches, JCAP10 (2013) 019 [arXiv:1307.5955] [INSPIRE].
S. Dutta, A. Goyal and L.K. Saini, Spin-0±portal induced dark matter, JHEP02 (2018) 023 [arXiv:1709.00720] [INSPIRE].
PandaX-II collaboration, Dark matter results from 54-ton-day exposure of PandaX-II experiment, Phys. Rev. Lett.119 (2017) 181302 [arXiv:1708.06917] [INSPIRE].
XENON collaboration, Physics reach of the XENON1T dark matter experiment, JCAP04 (2016) 027 [arXiv:1512.07501] [INSPIRE].
XENON collaboration, The XENON1T dark matter experiment, Eur. Phys. J.C 77 (2017) 881 [arXiv:1708.07051] [INSPIRE].
Fermi-LAT collaboration, Searching for dark matter annihilation from Milky Way dwarf spheroidal galaxies with six years of Fermi Large Area Telescope data, Phys. Rev. Lett.115 (2015) 231301 [arXiv:1503.02641] [INSPIRE].
Fermi-LAT collaboration, Fermi-LAT observations of high-energy γ-ray emission toward the galactic center, Astrophys. J.819 (2016) 44 [arXiv:1511.02938] [INSPIRE].
H.E.S.S. collaboration, Indirect dark matter searches with H.E.S.S, in the proceedings of the 15thInternational Conference on Supersymmetry and Unification of Fundamental Interactions (SUSY 2017), July 26-August 1, Karlsruhe, Germany (2007), arXiv:0710.2493 [INSPIRE].
M.N. Mazziotta, Indirect searches for dark matter with the Fermi LAT instrument, Int. J. Mod. Phys.A 29 (2014) 1430030 [arXiv:1404.2538] [INSPIRE].
R. Essig, N. Sehgal and L.E. Strigari, Bounds on cross-sections and lifetimes for dark matter annihilation and decay into charged leptons from gamma-ray observations of dwarf galaxies, Phys. Rev.D 80 (2009) 023506 [arXiv:0902.4750] [INSPIRE].
T. Bringmann, L. Bergstrom and J. Edsjo, New gamma-ray contributions to supersymmetric dark matter annihilation, JHEP01 (2008) 049 [arXiv:0710.3169] [INSPIRE].
A. Birkedal, K.T. Matchev, M. Perelstein and A. Spray, Robust gamma ray signature of WIMP dark matter, hep-ph/0507194 [INSPIRE].
C. Siqueira, Secluded dark matter in light of the Cherenkov Telescope Array (CTA), arXiv:1901.11055 [INSPIRE].
F.S. Queiroz and C. Siqueira, Search for semi-annihilating dark matter with Fermi-LAT, H.E.S.S., Planck and the Cherenkov Telescope Array, JCAP04 (2019) 048 [arXiv:1901.10494] [INSPIRE].
S. Profumo, F.S. Queiroz, J. Silk and C. Siqueira, Searching for Secluded Dark Matter with H.E.S.S., Fermi-LAT and Planck, JCAP03 (2018) 010 [arXiv:1711.03133] [INSPIRE].
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Dutta, S., Goyal, A. & Singh, M.P. Lepto-philic 2-HDM + singlet scalar portal induced fermionic dark matter. J. High Energ. Phys. 2019, 76 (2019). https://doi.org/10.1007/JHEP07(2019)076
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DOI: https://doi.org/10.1007/JHEP07(2019)076