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Article

New Light H± Discovery Channels at the LHC

1
Faculty of Sciences and Techniques, Abdelmalek Essaadi University, Tanger 90000, Morocco
2
Laboratoire de Physique Fondamentale et Appliquée Safi, Faculté Polydisciplinaire de Safi, Safi 46000, Morocco
3
Polydisciplinary Faculty, Research Team in Theoretical Physics and Materials (RTTPM), Sultan Moulay Slimane University, Beni Mellal 23000, Morocco
4
School of Physics and Astronomy, University of Southampton, Southampton SO17 1BJ, UK
5
College of Physics and Electronic Information, Inner Mongolia Normal University, Hohhot 010022, China
6
Center for Future High Energy Physics, Chinese Academy of Sciences, Beijing 100049, China
7
School of Physics Sciences, University of Chinese Academy of Sciences, Beijing 100039, China
*
Author to whom correspondence should be addressed.
Symmetry 2021, 13(12), 2319; https://doi.org/10.3390/sym13122319
Submission received: 9 October 2021 / Revised: 4 November 2021 / Accepted: 22 November 2021 / Published: 4 December 2021
(This article belongs to the Special Issue Symmetry, Collider Phenomenology and High Energy Physics)

Abstract

:
A light charged Higgs boson has been searched for at the Large Hadron Collider (LHC) via top (anti)quark decay, i.e., t b H + , if kinematically allowed. In this contribution, we propose new channels for light charged Higgs boson searches via the pair productions p p H ± h / A and p p H + H at the LHC in the context of the Two-Higgs Doublet Model (2HDM) Type-I. By focusing on a case where the heavy H state is the Standard Model (SM)-like one already observed, we investigate the production of the aforementioned charged Higgs bosons and their bosonic decay channels, namely, H ± W ± h and/or H ± W ± A . We demonstrate that such production and decay channels can yield substantial alternative discovery channels for H ± bosons at the LHC. Finally, we propose eight benchmark points (BPs) to motivate the search for such signatures.

1. Introduction

With the discovery of a 125 GeV Higgs boson at the Large Hadron Collider (LHC) [1,2] in 2012, the verification of the Standard Model (SM) of particle physics was completed. However, despite its agreement with the experiment, the SM is certainly not an ultimate theory. Thus, any extension of the SM is well motivated. One of the simplest and most straightforward extensions of the SM, which deserves particular attention, is the Two-Higgs Doublet Model (2HDM). The model contains two Higgs doublet fields that can generate masses for all (massive) fermions and gauge bosons. The scalar sector of 2HDM contains two charge-parity (CP)-even Higgs bosons, h and H (conventionally the mass of h is less than the mass of H, M h < M H ); one CP-odd Higgs boson, A; and a pair of charged Higgs bosons, H ± (in addition to the fermions and gauge bosons of the SM).
At the LHC, a light H ± boson has been searched for via the decay of a top (anti)quark ( t t ¯ ) if kinematically allowed. Typically, this process can be calculated using the usual method of factorizing the production process of proton–proton collisions, p p t t ¯ , times the decay one, t ¯ b ¯ H , in the narrow-width approximation (NWA). However, if the mass of the charged Higgs boson approaches the maximum, this approximation becomes invalid, and thus it is quite appropriate to target the process p p t b ¯ H to search instead [3]. This contribution revisits these two H ± production channels for the upcoming LHC Run 3 and compares them to the pair productions p p H ± h / A and p p H + H in the 2HDM Type-I. We show that signatures from such pair productions followed by H ± W ± h and/or H ± W ± A decays may lead to new discovery channels for light charged Higgs bosons searches at the LHC.
The contribution is organized as follows. First, we briefly describe the 2HDM and its Yukawa scenarios in Section 2. In Section 3, we explain the scan of the parameter space and the applied constraints. We discuss the numerical results and the selected benchmark points (BPs) in Section 4 and Section 5, and we finally conclude in Section 6.

2. The 2HDM

The CP -conserving 2HDM scalar potential, which is renormalizable and invariant under S U ( 2 ) L U ( 1 ) Y with a softly broken Z 2 symmetry, can be written as
V ( ϕ 1 , ϕ 2 ) = m 11 2 ( ϕ 1 ϕ 1 ) + m 22 2 ( ϕ 2 ϕ 2 ) [ m 12 2 ( Φ 1 ϕ 2 ) + h . c . ] + 1 2 λ 1 ( ϕ 1 ϕ 1 ) 2 + 1 2 λ 2 ( ϕ 2 ϕ 2 ) 2 + λ 3 ( ϕ 1 ϕ 1 ) ( ϕ 2 ϕ 2 ) + λ 4 ( ϕ 1 ϕ 2 ) ( ϕ 2 ϕ 1 ) + 1 2 λ 5 [ ( ϕ 1 ϕ 2 ) 2 + h . c . ] ,
where m 11 2 , m 22 2 and m 12 2 are squared mass parameters, and λ 1 5 are dimensionless coupling parameters. ϕ 1 , 2 are the Higgs doublet fields with v 1 , 2 as their respective vacuum expectation values (VEVs) such that v 1 2 + v 2 2 = v 2 ( 246 GeV ) 2 (where v is the SM Higgs VEV). Using the two minimization conditions of the potential, m 11 2 , m 22 2 and λ 1 5 can be substituted by v 1 , 2 , the physical mass eigenstates and sin ( β α ) , where α and β are the mixing angles. Thus, we are left with only seven independent parameters:
M h , M H , M A , M H ± , α , tan β and m 12 2 .
In the Yukawa sector, though, the flavor changing neutral currents (FCNCs) can be induced at the tree level if both the Higgs doublets of the general 2HDM couple to all fermions. To avoid FCNCs, which would be inconsistent with the experiment, a Z 2 symmetry can be enforced in such a way that each fermion type ( u , d , l ) acquires mass from one of the Higgs doublets. Thus, there are four possible types of 2HDM [4]. In 2HDM Type-I, the fermions acquire mass via the interaction with the doublet ϕ 2 as in the SM. In 2HDM Type-X (or lepton-specific), the charged leptons acquire mass from ϕ 1 while all quarks receive mass from ϕ 2 . In 2HDM Type-II, up-type quarks acquire mass through their interactions with ϕ 2 , and down-type quarks and charged leptons acquire mass through their interactions with ϕ 1 . Finally, in 2HDM Type-Y (or flipped), the up-type quarks and charged leptons receive mass from ϕ 2 , and down-type quarks receive mass from ϕ 1 . Here, though, we only consider 2HDM Type-I.
The Yukawa Lagrangian, which describes the coupling of the neutral and charged Higgs bosons to quarks and leptons, can be written as [4]:
L Yukawa = f = u , d , l m f v κ f h f ¯ f h + m f v κ f H f ¯ f H i m f v κ f A f ¯ γ 5 f A + V u d 2 v u ¯ ( m u κ u A P L + m d κ d A P R ) d H + + m l κ l A 2 v ν ¯ L l R H + + H . c . ,
where m f ( f = u , d , l ) are the masses of the fermions and κ f S are the Yukawa couplings, which are given in Table 1 for Type-I. V u d denotes the Cabibbo–Kobayashi–Maskawa (CKM) matrix element, and m u and m d are the masses of up and down quarks, respectively. P L , R represent the left-handed and right-handed projection operators.

3. Parameter Space Scans

In what follows, we perform a broad scan of the following 2HDM Type-I parameter space, where the H state is assumed to be the observed SM-like Higgs at the LHC in 2012 with mass fixed to 125 GeV:
M h = 10 120 GeV ; M H = 125 GeV ; M A = 10 120 GeV ; M H ± = 80 170 GeV tan β = 2 60 ; sin ( β α ) = ( 0.3 ) ( 0.05 ) ; m 12 2 = 0 M H 2 sin β cos β .
In the scan, the theoretical and experimental constraints are taken into account. 2HDMC [5] is used to check unitarity, perturbativity, vacuum stability and the electroweak oblique parameters (S, T and U). HiggsBounds-5.9.0 [6] and HiggsSignals-2.6.0 [7] are both used to enforce the exclusion bounds at the 95% confidence level (CL) from Higgs boson searches at LEP, Tevatron and LHC, and to check agreement with SM-like Higgs boson measurements, respectively. Constraints from flavour physics are tested using the public code SuperIso v4.1 [8].

4. Results

In the present contribution, we target the signatures of light charged Higgs bosons from processes involving top quarks and di-Higgs processes, i.e., g g , q q ¯ t t ¯ t b ¯ H + c.c. (NWA), g g , q q ¯ t b ¯ H + c.c., q q ¯ H + H plus q q ¯ H + h / A + c.c. taking into account their either W ± h or W ± A decays, where h and A decay into a pair of bottom quarks. (We are only interested here in the 4 b final states; see [9] for the 2 b 2 τ and 4 τ final states.) Relevant LHC signatures are summarized in Table 2.
In what follows, we show the production rates of relevant final states from different scenarios. In Figure 1, we compare W + 4 b and 2 W + 4 b signatures from p p H ± h W ± h h and p p H + H W + W h h with σ 2 t ( 2 W + 4 b ) (left panel) and σ t ( 2 W + 4 b ) (right panel) ones from the two top (anti)quark processes. Analogously to Figure 1, the same signatures from p p H ± A W ± A A and p p H + H W + W A A are compared with those from processes involving the top (anti)quark in Figure 2. From these plots, it is therefore clear that signatures from di-Higgs processes can yield substantial alternative discovery modes for charged Higgs bosons at the LHC in the context of the 2HDM Type I.

5. Benchmark Points

In order to encourage future searches for light charged Higgs boson via such new channels, we propose eight BPs for 2HDM Type-I. These BPs are presented in Table 3. In our selected BPs, notice that we take also into account the case where the mass of the charged Higgs is larger than that of the top one. The total cross-sections of the final states 2 W + 4 b and W + 4 b from both di-Higgs and the two top (anti)quarks are given herein.
In BP1, for instance, the cross-section rate of the 2 W + 4 b signature from the top (anti)quark processes can only reach 5 fb (we refer here to the p p t b ¯ H + c.c. rates), whereas the cross-section rate of the 2 W + 4 b signature from the pair production of H ± bosons is ≈23.1 fb. Moreover, the cross-section rate σ ( W + 4 b ) from the h / A -associated H ± production can reach values of around 174 fb, which are much larger than the rates of σ ( 2 W + 4 b ) from charged Higgs pair production. This behavior is well illustrated in Figure 3. For other BPs, the cross-section rates of the 2 W + 4 b and W + 4 b signatures from different production processes are also shown in Figure 3.

6. Conclusions

In this contribution, we have investigated the production of charged Higgs bosons through p p H ± h / A and p p H + H at the LHC with s = 14 TeV in 2HDM Type-I, after satisfying all theoretical and experimental constraints. By focusing on H ± W ± h / A decays, we have suggested the 2 W + 4 b and W + 4 b signatures as possible alternative discovery modes. We have demonstrated that such signatures could well be the most promising discovery for light H ± states. Thus, to motivate experimentalists to search for these, we have proposed eight BPs amenable to experimental investigation.

Author Contributions

Conceptualization, A.A., R.B., M.K., B.M., S.M., Y.W. and Q.-S.Y.; data curation, A.A., R.B., M.K., B.M., S.M., Y.W. and Q.-S.Y.; formal analysis, A.A., R.B., M.K., B.M., S.M., Y.W. and Q.-S.Y.; investigation, A.A., R.B., M.K., B.M., S.M., Y.W. and Q.-S.Y.; project administration, A.A., R.B., M.K., B.M., S.M., Y.W. and Q.-S.Y.; software, A.A., R.B., M.K., B.M., S.M., Y.W. and Q.-S.Y.; supervision, A.A., R.B., M.K., B.M., S.M., Y.W. and Q.-S.Y.; validation, A.A., R.B., M.K., B.M., S.M., Y.W. and Q.-S.Y.; visualization, A.A., R.B., M.K., B.M., S.M., Y.W. and Q.-S.Y.; writing—review and editing, A.A., R.B., M.K., B.M., S.M., Y.W. and Q.-S.Y. All authors have contributed in equal parts to all aspects of this research. All authors have read and agreed to the published version of the manuscript.

Funding

The work of A.A., R.B., M.K. and B.M. is supported by the Moroccan Ministry of Higher Education and Scientific Research MESRSFC and CNRST Project PPR/2015/6. The work of S.M. is supported in part through the NExT Institute and the STFC Consolidated Grant ST/L000296/1. Y.W. is supported by the “Scientific Research Funding Project for Introduced High-level Talents” of the Inner Mongolia Normal University, grant number 2019YJRC001. Q.-S.Y.’s work is supported by the Natural Science Foundation of China, grant number 11875260.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Conflicts of Interest

The authors declare no conflict of interest.

References

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Figure 1. Total cross-sections σ ( p p H ± h ) × BR ( H ± W ± h ) × BR ( h b b ¯ ) 2 are shown against those of 2 σ t t ¯ × BR ( t b H + ) × BR ( t ¯ b ¯ W ) × BR ( H ± W ± h ) × BR ( h b b ¯ ) (left) and σ ( p p t b ¯ H ) × BR ( t b W + ) × BR ( H ± W ± h ) × BR ( h b b ¯ ) (right). The red points refer to the total cross-sections σ ( p p H + H ) × BR ( H ± W ± h ) 2 × BR ( h b b ¯ ) 2 , which are also large compared to the two top production processes. The mass of the charged Higgs boson, M H ± , is indicated by the color map.
Figure 1. Total cross-sections σ ( p p H ± h ) × BR ( H ± W ± h ) × BR ( h b b ¯ ) 2 are shown against those of 2 σ t t ¯ × BR ( t b H + ) × BR ( t ¯ b ¯ W ) × BR ( H ± W ± h ) × BR ( h b b ¯ ) (left) and σ ( p p t b ¯ H ) × BR ( t b W + ) × BR ( H ± W ± h ) × BR ( h b b ¯ ) (right). The red points refer to the total cross-sections σ ( p p H + H ) × BR ( H ± W ± h ) 2 × BR ( h b b ¯ ) 2 , which are also large compared to the two top production processes. The mass of the charged Higgs boson, M H ± , is indicated by the color map.
Symmetry 13 02319 g001
Figure 2. Total cross-sections of σ ( p p H ± A ) × BR ( H ± W ± A ) × BR ( A b b ¯ ) 2 are shown against those of 2 σ t t ¯ × BR ( t b H + ) × BR ( t ¯ b ¯ W ) × BR ( H ± W ± A ) × BR ( A b b ¯ ) (left) and σ ( p p t b ¯ H ) × BR ( t b W + ) × BR ( H ± W ± A ) × BR ( A b b ¯ ) (right). The red points refer to the total cross-sections σ ( p p H + H ) × BR ( H ± W ± A ) 2 × BR ( A b b ¯ ) 2 which are also large compared to the two top production processes. The mass of the charged Higgs boson, M H ± , is indicated by the color map.
Figure 2. Total cross-sections of σ ( p p H ± A ) × BR ( H ± W ± A ) × BR ( A b b ¯ ) 2 are shown against those of 2 σ t t ¯ × BR ( t b H + ) × BR ( t ¯ b ¯ W ) × BR ( H ± W ± A ) × BR ( A b b ¯ ) (left) and σ ( p p t b ¯ H ) × BR ( t b W + ) × BR ( H ± W ± A ) × BR ( A b b ¯ ) (right). The red points refer to the total cross-sections σ ( p p H + H ) × BR ( H ± W ± A ) 2 × BR ( A b b ¯ ) 2 which are also large compared to the two top production processes. The mass of the charged Higgs boson, M H ± , is indicated by the color map.
Symmetry 13 02319 g002
Figure 3. Cross-section rates of 2 W + 4 b and W + 4 b signatures for the selected BPs.
Figure 3. Cross-section rates of 2 W + 4 b and W + 4 b signatures for the selected BPs.
Symmetry 13 02319 g003
Table 1. Yukawa couplings of the neutral Higgs bosons h, H and A to quarks and leptons in 2HDM Type-I.
Table 1. Yukawa couplings of the neutral Higgs bosons h, H and A to quarks and leptons in 2HDM Type-I.
κ u S κ d S κ S
h   cos α / sin β    cos α / sin β    cos α / sin β  
H   sin α / sin β    sin α / sin β    sin α / sin β  
A   cot β    cot β    cot β  
Table 2. Charged Higgs bosons production modes and their final states. σ t t ¯ denotes the production process of proton–proton collisions, p p t t ¯ , and BR refers to the branching ratio. Here, h i ( i = 1 , 2 ) refers to h 1 = h and h 2 = A .
Table 2. Charged Higgs bosons production modes and their final states. σ t t ¯ denotes the production process of proton–proton collisions, p p t t ¯ , and BR refers to the branching ratio. Here, h i ( i = 1 , 2 ) refers to h 1 = h and h 2 = A .
Higgs Production and Decay Process
σ 2 t h i ( 2 W + 4 b ) 2   σ t t ¯ × BR ( t b H + ) × BR ( t ¯ b ¯ W ) × BR ( H ± W ± h i ) × BR ( h i b b ¯ )
σ t h i ( 2 W + 4 b ) σ ( p p t b ¯ H ) × BR ( t b W + ) × BR ( H ± W ± h i ) × BR ( h i b b ¯ )
σ h i h i ( 2 W + 4 b ) σ ( p p H + H ) × BR ( H ± W ± h i ) 2 × BR ( h i b b ¯ ) 2
  σ h i h i ( W + 4 b ) σ ( p p H ± h i ) × BR ( H ± W ± h i ) × BR ( h i b b ¯ ) 2
Table 3. Mass spectra (in GeV), mixing angles and cross-sections (in fb) for the selected BPs. (Notice that all these parameters have been discussed above).
Table 3. Mass spectra (in GeV), mixing angles and cross-sections (in fb) for the selected BPs. (Notice that all these parameters have been discussed above).
ParametersBP1BP2BP3BP4BP5BP6BP7BP8
M h 91.00 96.84 103.34 99.61 95.57 94.00 94.00 94.00
M H 125.00 125.00 125.00 125.00 125.00 125.00 125.00 125.00
M A 102.04 112.35 93.80 88.98 94.41 105.00 105.00 105.00
M H ± 167.02 166.34 161.02 169.46 167.02 176.00 186.00 196.00
sin ( β α ) 0.18 0.11 0.19 0.06 0.09 0.09 0.09 0.09
tan β 40.87 58.17 54.79 39.10 32.44 30.00 30.00 30.00
m 12 2 204.22 161.85 196.73 252.94 277.81 294.00 294.00 294.00
σ 2 t h ( 2 W + 4 b ) 2.30 1.65 2.06 2.42
σ t h ( 2 W + 4 b ) 3.85 2.35 2.26 0.85 3.84 5.03 4.68 3.52
σ 2 t A ( 2 W + 4 b ) 0.70 0.25 4.63 2.47
σ t A ( 2 W + 4 b ) 1.17 0.36 5.07 3.03 3.92 0.83 0.44 1.08
σ h h ( 2 W + 4 b ) 13.58 15.99 2.29 0.97 5.38 14.08 13.27 7.35
σ A h ( 2 W + 4 b ) 4.13 2.44 5.14 3.46 5.50 2.32 1.25 2.24
σ A A ( 2 W + 4 b ) 1.26 0.37 11.55 12.35 5.62 0.38 0.12 0.68
σ h A ( 2 W + 4 b ) 4.13 2.44 5.14 3.46 5.50 2.32 1.25 2.24
σ h h ( W + 4 b ) 75.88 77.61 26.47 17.68 46.00 73.25 68.00 48.81
σ A h ( W + 4 b ) 23.07 11.86 59.44 63.04 47.00 12.07 6.42 14.90
σ A A ( W + 4 b ) 17.48 6.12 64.39 69.22 43.51 9.16 4.91 11.45
σ h A ( W + 4 b ) 57.51 40.06 28.68 19.41 42.59 55.59 52.02 37.51
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Arhrib, A.; Benbrik, R.; Krab, M.; Manaut, B.; Moretti, S.; Wang, Y.; Yan, Q.-S. New Light H± Discovery Channels at the LHC. Symmetry 2021, 13, 2319. https://doi.org/10.3390/sym13122319

AMA Style

Arhrib A, Benbrik R, Krab M, Manaut B, Moretti S, Wang Y, Yan Q-S. New Light H± Discovery Channels at the LHC. Symmetry. 2021; 13(12):2319. https://doi.org/10.3390/sym13122319

Chicago/Turabian Style

Arhrib, Abdesslam, Rachid Benbrik, Mohamed Krab, Bouzid Manaut, Stefano Moretti, Yan Wang, and Qi-Shu Yan. 2021. "New Light H± Discovery Channels at the LHC" Symmetry 13, no. 12: 2319. https://doi.org/10.3390/sym13122319

APA Style

Arhrib, A., Benbrik, R., Krab, M., Manaut, B., Moretti, S., Wang, Y., & Yan, Q. -S. (2021). New Light H± Discovery Channels at the LHC. Symmetry, 13(12), 2319. https://doi.org/10.3390/sym13122319

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