Hieu Minh Tran scite author profile

The gauge kinetic mixing in general is allowed in models with multiple Abelian gauge groups. In this paper, we investigate the gauge kinetic mixing in the framework of U(1) extensions of the MSSM. It enlarges the viable parameter space, and has an important effect on the particle mass spectrum as well as the Z 2 coupling with matters. The SM-like Higgs boson mass can be enhanced with a nonzero kinetic mixing parameter and the muon g − 2 tension is slightly less severe than in the case of no mixing. We present the results from both benchmark analysis and global parameter scan. Various theoretical and phenomenological constraints have been considered. The recent LHC searches for the Z 2 boson are important for the case of large positive kinetic mixing where the Z 2 coupling is enhanced, and severely constrain scenarios with M Z 2 < 2.8 TeV. The viable dark matter candidate predicted by the model is either the neutralino or the right-handed sneutrino. Cosmological constraints from dark matter searches play a significant role in excluding the parameter space. Portions of the parameter space with relatively low sparticle mass spectrum can be successfully explored in the LHC run-2 as well as future linear colliders and dark matter searches.

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Analysis and assessment of LoRaWAN

Phung

Tran

Nguyen

et al. 2018

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Positively deflected anomaly mediation in the light of the Higgs boson discovery

Okada

Tran

2013

Phys. Rev. D

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Anomaly mediated supersymmetry breaking (AMSB) is a well-known mechanism for flavorblind transmission of supersymmetry breaking from the hidden sector to the visible sector. However, the pure AMSB scenario suffers from a serious drawback, namely, the tachyonic slepton problem, and needs to be extended. The so-called (positively) deflected AMSB is a simple extension to solve the problem and also provides us with the usual neutralino lightest superpartner (LSP) as a good candidate for dark matter in the Universe. Motivated by the recent discovery of the Higgs boson at the large hadron collider (LHC) experiments, we perform the parameter scan in the deflected AMSB scenario by taking into account a variety of phenomenological constraints such as the dark matter relic density and the observed Higgs boson mass around 125-126 GeV. We identify the allowed parameter region and list benchmark mass spectra. We find that in most of the allowed parameter regions, the dark matter neutralino is Higgsino-like and its cross section of the elastic scattering with nuclei is within the future reach of the direct dark matter search experiments, while (colored) sparticles are quite heavy and their discovery at the LHC is challenging.

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GUT-inspired MSSM in light of muon g−2 and LHC results at s=13 TeV

Tran

Nguyen

2019

Phys. Rev. D

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The recent results of the LHC search for electroweak production of supersymmetric (SUSY) particles at √ s = 13 TeV have shown improved lower limits for their masses. In addition, the projected experiment E989 will be able to measure the muon anomalous magnetic moment precisely so that the experimental uncertainty can be reduced by a factor of four. It was pointed out that if the center value of the muon g − 2 remains unchanged the deviation between the standard model (SM) prediction and the experimental value will be as large as 7.0σ. Such a large deviation will be solid evidence for new physics beyond the SM. Motivated by these results, we investigate the minimal SUSY extension of the SM with universal gaugino masses at the grand unified scale in the light of the muon g − 2 and the updated LHC constraints. The squarks are assumed to be heavy and decoupled from physics at low energy scales to resemble the SM-like Higgs boson mass of 125 GeV and other bounds for squark masses at the LHC. We have pinned down allowed windows for the lightest neutralino and the smuon masses as well as other input parameters relevant to the light SUSY sector. The expected results of the E989 experiment play a crucial role in narrowing these windows. The viability of the model for small mass regions can be tested at the LHC Run 3 and the High Luminosity LHC in the near future.Recently, the Large Hadron Collider (LHC) data at √ s = 13 TeV with the luminosity of 2 With large stop mixing, the stop masses can be as light as 2 − 4 TeV [13].

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125 GeV Higgs boson mass and muon g−2 in 5D MSSM

Okada

Tran

2016

Phys. Rev. D

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In the MSSM, the tension between the observed Higgs boson mass and the experimental result of the muon g − 2 measurement requires a large mass splitting between stops and smuons/charginos/neutralinos. We consider a 5-dimensional (5D) framework of the MSSM with the Randall-Sundrum warped background metric, and show that such a mass hierarchy is naturally achieved in terms of geometry. In our setup, the supersymmetry is broken at the ultraviolet (UV) brane, while all the MSSM multiplets reside in the 5D bulk. An appropriate choice of the bulk mass parameters for the MSSM matter multiplets can naturally realize the sparticle mass hierarchy desired to resolve the tension. Gravitino is localized at the UV brane and hence becomes very heavy, while the gauginos spreading over the bulk acquire their masses suppressed by the 5th dimensional volume. As a result, the LSP neutralino is a candidate for the dark matter as usual in the MSSM. In addition to reproducing the SM-like Higgs boson mass of around 125 GeV and the measured value of the muon g − 2, we consider a variety of phenomenological constraints, and present the benchmark particle mass spectra which can be explored at the LHC Run-2 in the near future.

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Hieu Minh Tran

Dark matter in U(1) extensions of the MSSM with gauge kinetic mixing

Analysis and assessment of LoRaWAN

Positively deflected anomaly mediation in the light of the Higgs boson discovery

GUT-inspired MSSM in light of muon g−2 and LHC results at s=13 TeV

125 GeV Higgs boson mass and muon g−2 in 5D MSSM

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