The production potential of the excited neutrinos at the FCC-based electron-hadron colliders, namely, the ERL60⊗FCC with s=3.46 TeV, the ILC⊗FCC with s=10 TeV, and the PWFA-LC⊗FCC with s=31.6 TeV, has been analyzed. The branching ratios of the excited neutrinos have been calculated for the different decay channels and shown that the dominant channel is ν⋆→eW+. We have calculated the production cross sections with the process of ep→ν⋆q→eW+q and the decay widths of the excited neutrinos with the process of ν⋆→eW+. The signals and corresponding backgrounds are studied in detail to obtain accessible mass limits. It is shown that the discovery limits obtained on the mass of the excited neutrino are 2452 GeV for Lint=100fb-1, 5635 GeV for Lint=10fb-1 (6460 GeV for Lint=100fb-1), and 10200 GeV for Lint=1fb-1 (13960 GeV for Lint=10fb-1), for the center-of-mass energies of 3.46, 10, and 31.6 TeV, respectively.
Türkiye Bilimsel ve Teknolojik Arastirma Kurumu114F3371. Introduction
The Standard Model (SM) of particle physics has so far been in agreement with the results of numerous experiments. The discovery of the Higgs boson [1] has also increased the reliability of the SM. However, there are some problems which have not been entirely solved by the SM, such as quark-lepton symmetry, family replication, number of families, fermion’s masses and mixing pattern, and hierarchy problems. Several theories beyond the SM (BSM), including extra dimensions, supersymmetry (SUSY), and compositeness, have been proposed to solve these problems. The best way to explain the inflation of fundamental particles in the SM is to assume that they have more fundamental matter constituents. Therefore, a natural explanation for the replication of the SM fermionic families is lepton and quark compositeness, in which both matter and antimatter elementary particles have a substructure called preon [2]. The composite models have been characterized by an energy scale, namely, compositeness scale, Λ. A typical consequence of the compositeness is the appearance of excited leptons and quarks [3, 4]. Charged e⋆,μ⋆,τ⋆ and neutral (νe⋆,νμ⋆,ντ⋆) excited leptons are predicted by the composite models. The SM fermions are considered as ground states of a rich and heavier spectrum of the excited states. An excited spin-1/2 lepton is considered to be both the lowest radial and orbital excitation. Excited states with spin-3/2 are also expected to exist [5].
No evidence for excited lepton production has been found so far in searches based on data samples collected by the LEP [6], HERA [7], Tevatron [8], CMS [9], and ATLAS [10] experiments. For the excited electron [11, 12], muon [13], and neutrino [14–17], there are some phenomenological studies at the future high-energy colliders.
Current experimental lower bounds on the masses of the excited neutrinos are mν⋆>102.6 GeV [6] from LEP-L3 collaboration (pair production) assuming f=-f′=1, mν⋆>213 GeV [18] at 95% CL from HERA-H1 collaboration (single production) assuming f=f′=1 and mν⋆>1.6 TeV [18], namely, the strongest limit, from LHC-ATLAS collaboration (pair production) assuming f=f′=1.
The Future Circular Collider (FCC) is a post-Large Hadron Collider (LHC) accelerator project [19], with s=100 TeV, proposed at CERN and supported by European Union within the Horizon 2020 Framework Programme for Research and Innovation. Besides the pp option, FCC also includes e+e- collider option (TLEP) at the same tunnel [20]. Construction of the future e+e- and μ+μ- colliders tangential to the FCC will also provide several ep and μp collider options [21].
In this paper, we analyze the potential of the FCC-based ep colliders, namely, ERL60⊗FCC, ILC⊗FCC, and PWFA-LC⊗FCC, for the excited neutrino searches. The ERL60 denotes energy recovery linac proposed for the LHeC main option [22] and can also be used for the FCC-based ep colliders. The ILC and the PWFA-LC mean International Linear Collider [23] and Plasma Wake Field Accelerator Linear Collider [24], respectively. The FCC-based ILC⊗FCC and PWFA-LC⊗FCC colliders have been proposed in [25]. Energy of the electron beams, center-of-mass energy, and luminosity values of the FCC-based ep colliders are presented in Table 1 [25, 26].
Main parameters of the FCC-based ep colliders.
Colliders
Ee (TeV)
CM energy (TeV)
Lint (fb-1 per year)
ERL60⊗FCC
0.06
3.46
100
ILC⊗FCC
0.5
10
10–100
PWFA-LC⊗FCC
5
31.6
1–10
We introduce the effective Lagrangian, the decay widths, and the branching ratios of the excited neutrinos in Section 2. In Section 3, we analyze the signal and backgrounds for the process ep→ν⋆q→eW+q, and finally we summarize our results in Section 4.
2. Production of the Excited Neutrinos
The interaction between a spin-1/2 excited lepton, a gauge boson V=γ,Z,W±, and the SM leptons is described by SU(2)×U(1) invariant Lagrangian [4, 27, 28] as(1)L=12ΛlR∗¯σμνfgτ→2·W→μν+f′g′Y2BμνlL+h.c.,where Λ is the new physics scale responsible for the existence of the excited leptons, W→μν and Bμν are the field strength tensors, g and g′ are the gauge couplings, f and f′ are the scaling factors for the gauge couplings of SU(2) and U(1), σμν=i(γμγν-γνγμ)/2 where γμ are the Dirac matrices, τ→ denotes the Pauli matrices, and Y is hypercharge.
For an excited neutrinos, three decay modes are possible: radiative decay ν⋆→νγ, neutral weak decay ν⋆→νZ, and charged weak decay ν⋆→eW+. The branching ratios (BR) of the excited neutrino for the couplings f=f′=1 and f=-f′=1 are given in Figure 1. One may note that the electromagnetic interaction between excited neutrino and ordinary neutrino, namely, γ-channel, vanishes for f=f′=1. As clearly visible from Figure 1, the W-channel, whose branching ratio is ~60%, is dominant in the whole mass range for f=f′=1. In the case of f=-f′=1, the branching ratio for the individual decay channels reaches the constant value of 60% for the W-channel, 12% for the Z-channel, and 28% for the γ-channel at higher neutrino masses (mν⋆>150 GeV). Since the charged weak decay (ν⋆→eW+) is dominant in both cases, we preferred this channel for investigating the excited neutrino in future linear collider experiments.
The branching ratios (%) depending on the mass of the excited neutrino for f=f′=1 (a) and f=-f′=1 (b).
Neglecting the SM lepton mass, we find the decay width of excited leptons as(2)Γl⋆⟶lV=αm⋆34Λ2fV21-mV2m⋆221+mV22m⋆2,where fV is the new electroweak coupling parameter corresponding to the gauge boson V, where V=W+, Z, γ, and fγ=f-f′/2, fZ=fcotθW+f′tanθW/2, fW=f/2sinθW, where θW is the weak mixing angle and mV is the mass of the gauge boson. The total decay widths of the excited neutrino for the scale Λ=mν⋆ is given in Figure 2.
The total decay widths of the excited neutrino for the scale Λ=mν⋆ and the coupling f=f′=1.
3. Signal and Background Analysis
We analyze the potentials of the future ep collider machines to search for the excited neutrinos via the single production reaction ep→ν⋆X with subsequent decay of the excited neutrino into an electron and a W+ boson. Therefore, we consider the process ep→W+eX and subprocesses eq(q¯)→W+eq(q¯). The signal and background analysis were done at the parton level by using the high-energy simulation program CALCHEP in the version 3.6.25 [29]. We used the CTEQ6L [30] parton distribution functions in our calculations.
For a comparison of different FCC-based ep colliders, the signal cross sections for excited neutrino production are presented in Figure 3, assuming the coupling parameter f=f′=1.
The total cross sections as a function of the excited neutrino mass at the ep colliders with various center-of-mass energies, assuming f=f′=1 and Λ=mν⋆.
3.1. ERL60⊗FCC Collider
The ERL60⊗FCC is a FCC-based future ep collider with the center-of-mass energy of 3.46 TeV. Keeping in mind that the lower bound on the mass of the excited neutrino is 1.6 TeV (mν⋆>1.6 TeV), we have explored the mass limits for the discovery of the excited neutrinos in the range of 1.6 and 3.46 TeV at the ERL60⊗FCC collider. To separate signal from backgrounds, final state particles (electron, W+ boson and jets) with pTe,W,j>20 GeV are required. The SM cross section after the application of these cuts is σB=3.96 pb. In order to define the kinematical cuts best suited for discovery, we have plotted the normalized transverse momentum and the normalized pseudorapidity distributions of the final state particles. Figure 4 shows the normalized pT distributions of the final state W+ bosons (a), pseudorapidity (η) distributions of the final state electron (b), and the η distributions of the final state W+ (c), for signals corresponding to excited neutrino masses of 1000 and 2000 GeV and the SM backgrounds. The pT distributions of the final state electrons are the same as those of the final state W+ bosons. As can be seen from Figure 4, the kinematical cuts pTW,e>200 GeV, -5<ηe<-1 and -4.5<ηW<-2 drastically reduce the background while keeping the signal almost unchanged. The invariant mass distributions of the eW+ system after the application of all kinematical cuts is reported in Figure 5. The separation of the signal from the background improved.
The normalized transverse momentum distributions of the final state W+ bosons (a), the normalized pseudorapidity distributions of the final state electrons (b), and the normalized pseudorapidity distributions of the final state W+ bosons (c) for f=f′=1 and Λ=mν⋆ at the ERL60⊗FCC collider.
The invariant mass distributions of the excited neutrino signal and the corresponding background for Λ=mν⋆ and f=f′=1 at the ERL60⊗FCC collider.
A natural way of extracting the excited neutrino signal, and the same time suppressing the SM background is to impose a cut on the eW+ invariant mass in addition to kinematical cuts. Therefore, we have selected events within the mass window mν⋆-2Γν⋆<meW<mν⋆+2Γν⋆.
We define statistical significance (SS) of the expected signal yield as(3)SS=σS+B-σBσBLint,where σS+B denotes the cross section due to the excited neutrino production and the SM backgrounds, σB denotes the SM cross section, and Lint is the integrated luminosity of the collider. Assuming f=f′=1 and Λ=mν⋆, we have calculated the signal, the background cross sections, and SS in eW+ invariant mass bins since the signal is concentrated in a small region proportional to the invariant mass resolution. The results are summarized in Table 2. The ERL60⊗FCC collider can discover the excited neutrino in ν⋆→W+e decay mode for the coupling f=f′=1 up to the mass of 2452 GeV taking into account the discovery criterion SS≥5 (99% CL).
The statistical significance (SS) values and the cross sections of the excited neutrino signal and relevant backgrounds at ERL60⊗FCC collider with s=3.46 TeV and Lint=100fb-1, assuming Λ=mν⋆ and f=f′=1.
Mass (GeV)
σS+B (pb)
σB (pb)
SS
1600
7.21×10-3
1.86×10-4
162.9
1800
2.47×10-3
9.60×10-5
76.5
2000
7.65×10-4
4.15×10-5
35.5
2200
2.09×10-4
1.49×10-5
15.9
2300
1.03×10-4
8.48×10-6
10.2
2400
4.82×10-5
4.64×10-6
6.4
2500
2.14×10-5
2.41×10-6
3.8
2600
8.85×10-6
1.19×10-6
2.2
2700
3.32×10-6
5.41×10-7
1.1
3.2. ILC⊗FCC Collider
The ILC⊗FCC collider with the center-of-mass energy of 10 TeV can search for the excited neutrino in a wider mass range compared to the ERL60⊗FCC collider. We have explored the mass limits for discovery of the excited neutrinos in the mass range from 1.6 to 10 TeV. In order to separate the excited neutrino signals from the background we have required pTe,W,j>20 GeV, as for the ERL60⊗FCC collider. Subsequently, the SM background cross section for the ILC⊗FCC collider is found to be σB=15.74 pb. The normalized pT distributions of the final state electrons, the η distributions of the final state W+ bosons, and the η distributions of the final state electrons are presented in Figure 6. Also in this case, final state electrons and W+ bosons have the same pT distribution. The kinematical cuts pTW,e>200 GeV, -3.4<ηW<0.4, and -5<ηe<1 are optimal for increasing the potential discovery. The invariant mass distributions of the eW+ system after the application of all kinematical cuts is reported in Figure 7.
The normalized transverse momentum distributions of the final state electrons (a), the normalized pseudorapidity distributions of the final state W+ bosons (b), and the normalized pseudorapidity distributions of the final state electrons (c) for f=f′=1 and Λ=mν⋆ at the ILC⊗FCC collider.
The invariant mass distributions of the excited neutrino signal and the corresponding background for Λ=mν⋆ and f=f′=1 at the ILC⊗FCC collider.
Signal and background cross sections in eW+ invariant mass bins mν⋆-2Γν⋆<meW<mν⋆+2Γν⋆ and the SS values calculated for Lint=10fb-1 and Lint=100fb-1 are summarized in Table 3.
The statistical significance (SS) values and the cross sections of the excited neutrino signal and relevant background at the ILC⊗FCC collider with s=10 TeV assuming the coupling f=f′=1 and the energy scale Λ=mν⋆.
Mass (GeV)
σB (pb)
σS+B (pb)
Lint=10fb-1
Lint=100fb-1
SS
SS
2000
1.81×10-3
1.47×10-1
342.1
1081.9
2500
1.24×10-3
5.85×10-2
162.9
515.1
3000
7.37×10-4
2.43×10-2
86.8
274.7
3500
3.94×10-4
1.03×10-2
49.6
157
4000
1.85×10-4
4.28×10-3
30
95.1
4500
8.27×10-5
1.74×10-3
18.1
57.4
5000
3.58×10-5
6.69×10-4
10.5
33.4
5500
1.47×10-5
2.43×10-4
5.9
18.8
6000
6.07×10-6
8.15×10-5
3
9.6
6500
2.26×10-6
2.49×10-5
1.5
4.7
7000
7.83×10-7
6.69×10-6
0.6
2.1
7500
2.37×10-7
1.49×10-6
0.2
0.8
Assuming f=f′=1 and Λ=mν⋆, taking into account the calculated SS values for SS≥5 criterion, the ILC⊗FCC collider can probe the excited neutrino up to the masses of 5635 and 6460 GeV for the integrated luminosities of Lint=10fb-1 and Lint=100fb-1, respectively.
3.3. PWFA-LC⊗FCC Collider
If the excited neutrinos had not been observed at the ERL60⊗FCC and the ILC⊗FCC colliders, they would have been explored up to the mass of 31.6 TeV at the PWFA-LC⊗FCC collider that has the widest research potential. We have explored the mass limits for discovering the excited neutrinos in a broad mass spectrum from 1.6 to 31.6 TeV. The SM background cross section is found to be σB=58.15 pb after the application of the same initial kinematical cuts. Figure 8 shows the pT distributions of the final state W+ bosons, the η distributions of the final state electrons, and the η distributions of the W+ boson for the excited neutrino masses of 5000, 10000, 15000, and 20000 GeV versus the backgrounds. As already discussed, the pT distributions of the W+ bosons are the same for the final state electrons. By requiring pTW,e>400 GeV -5<ηe<2.5, and -2.5<ηW<1, the background is suppressed, whereas the signal remains almost unchanged. The invariant mass distributions of the eW+ system obtained after application of all cuts is reported in Figure 9. We have also required the eW+ invariant masses to be in the range mν⋆-2Γν⋆<meW<mν⋆+2Γν⋆.
The normalized transverse momentum distributions of the final state W+ bosons (a), the normalized pseudorapidity distributions of the final state electrons (b), and the normalized pseudorapidity distributions of the final state W+ bosons (c) for f=f′=1 and Λ=mν⋆ at the PWFA-LC⊗FCC collider.
The invariant mass distributions of the excited neutrino signal and the corresponding background for Λ=mν⋆ and f=f′=1 at the PWFA-LC⊗FCC collider.
Assuming f=f′=1 and Λ=mν⋆, the signal and the background cross sections for PWFA-LC⊗FCC collider, as well as the SS values, are summarized in Table 4 for two integrated luminosity values, namely, Lint=1fb-1 and Lint=10fb-1. For the energy scale of Λ=mν⋆, the PWFA-LC⊗FCC collider can probe the excited neutrino up to the masses of 10200 and 13960 GeV for the integrated luminosities of Lint=1fb-1 and Lint=10fb-1, respectively.
The statistical significance (SS) values and the cross sections of the excited neutrino signal and relevant background at the PWFA-LC⊗FCC collider with s=31.6 TeV assuming the coupling f=f′=1 and the energy scale Λ=mν⋆.
Mass (GeV)
σB (pb)
σS+B (pb)
Lint=1fb-1
Lint=10fb-1
SS
SS
2000
1.16×10-3
2.92×10-1
270.5
855.6
4000
1.03×10-3
9.00×10-2
87.6
277.2
6000
6.30×10-4
2.42×10-2
29.7
93.9
8000
3.59×10-4
7.47×10-3
11.8
37.5
10000
1.78×10-4
2.45×10-3
5.3
17
12000
6.55×10-5
8.02×10-4
2.8
9.1
14000
2.27×10-5
2.57×10-4
1.5
4.9
16000
7.71×10-6
7.66×10-5
0.7
2.4
18000
2.51×10-6
2.06×10-5
0.3
1.1
20000
7.42×10-7
4.85×10-6
0.1
0.4
4. Conclusion
This work has shown that the FCC-based ep colliders have a great potential for the excited neutrino searches. We give a realistic estimate for the excited neutrino signal and the corresponding background at three different colliders, namely, the ERL60⊗FCC (s=3.46 TeV), the ILC⊗FCC (s=10 TeV), and the PWFA-LC⊗FCC (s=31.6 TeV). The simulations have been performed assuming the energy scale Λ=mν⋆ and the coupling parameter f=f′=1. The mass limits for exclusion, observation, and discovery of the excited neutrinos at the three colliders are given in Table 5, for the different integrated luminosity values. As a result, these three FCC-based ep colliders offer the possibility of probing the excited neutrino over a very large mass range.
The mass limits for the exclusion (2σ), the observation (3σ), and the discovery (5σ) of the excited neutrinos at the different ep colliders assuming the coupling f=f′=1 and the energy scale Λ=mν⋆.
Colliders
Lint (fb-1)
2σ (GeV)
3σ (GeV)
5σ (GeV)
ERL60⊗FCC
100
2618
2547
2452
ILC⊗FCC
10
6300
6000
5635
100
7025
6790
6460
PWFA-LC⊗FCC
1
13050
11850
10200
10
16500
15450
13960
Conflicts of Interest
The author declares that he has no conflicts of interest.
Acknowledgments
The author is grateful to A. Ozansoy and S. O. Kara for useful discussions and model file supports. This work has been supported by the Scientific and Technological Research Council of Turkey (TUBITAK) under Grant no. 114F337.
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