1 Introduction

Electroweak symmetry breaking is a cornerstone for our understanding of particle physics. However, despite the spectacular phenomenological success of the Standard Model (SM), the fundamental mechanism of electroweak symmetry breaking remains a mystery. Various new models have been proposed to explain this mechanism. One such class of models is based upon topcolor [13] which can generate a large top-quark mass. The topcolor model also predicts a Z′ [4].

The physics in production and decay of the Z′ are discussed in Ref. [4] under different model assumptions. In this paper, we consider the Z′ from Model IV which represents a novel class and has predicted cross sections large enough to be experimentally accessible at hadron colliders at the Fermilab Tevatron and the Large Hadron Collider (LHC) at CERN. Such Z′ resonances couple strongly only to the first and third generations of quarks, and have no significant couplings to the leptons. They are, therefore, leptophobic and topophyllic.

This article presents an updated calculation valid for the Tevatron and all proposed LHC collision energies. The leptophobic topcolor Z′ decaying to \(t\bar{t}\) has been searched for at both the Tevatron [57] and the LHC [8]. The Tevatron searches used a previous calculation of the Z′ cross section [4]. The LHC search conducted by the CMS collaboration have used the cross section calculation presented here to set limits on the Z′ mass. This article is primarily intended to document that Z′ cross section used for a pp collision energy of \(\sqrt{s} = 7\mbox{~TeV}\). For current and future LHC searches, we present the Z′ cross section at the current LHC pp collision energy of \(\sqrt{s} = 8\mbox{~TeV}\) and the potential future collision energies of 10 and 14 TeV. We also present the cross section in \(p\bar{p}\) collisions at \(\sqrt{s} = 2\mbox{~TeV}\) for comparison with Tevatron searches.

2 Model

As discussed in Ref. [4], non-standard models can be constructed in which the U(1) Y U(1)1×U(1)2 and the generations are grouped differently. Model IV is the case where quark generations (1,3)⊃U(1)2. The dominant part of the interaction Lagrangian for Model IV is

(1)

where g 1 is the SM coupling constant, and we require the following: f 1>0 (attractive \(\bar{t}t\) channel) and/or f 2<0 (repulsive \(\bar{b}b\) channel). Also, cotθ H ≫1 to avoid fine-tuning. The parton-level subprocess cross section that we use in the next section is obtained from this Lagrangian.

3 Cross section for Z′ production and decay

The total lowest-order cross section for a Z′ produced in hadron collisions and decaying into top–antitop pairs from Model IV, discussed above, is given by

$$ \sigma_{Z'} \times \mathrm{B}\bigl(Z'\rightarrow t\bar{t} \bigr) \equiv \sigma= \int_{0}^{\infty} \frac{d\sigma}{dm} \,dm $$
(2)

where /dm, the differential cross section at \(t\bar{t}\) invariant mass m, is given by

(3)

Here \(\hat{\sigma}(q\bar{q} \rightarrow Z' \rightarrow t\bar{t})\) is the parton-level subprocess cross section. The kinematic variable τ is related to the initial-state parton fractional momenta inside the first hadron x h1 and the second hadron x h2 by τ=x h1 x h2=m 2/s. The boost of the partonic system y b is given by y b =(1/2)ln(x h1/x h2). The partonic “luminosity function” is just the product of parton distribution functions:

(4)

where q(x,μ) (\(\bar{q}(x,\mu)\)) is the parton distribution function of a quark (anti-quark) evaluated at fractional momenta x and renormalization scale μ.

The parton-level subprocess cross section, \(\hat{\sigma}(q\bar{q} \rightarrow Z' \rightarrow t\bar{t})\), for a leptophobic, b r -phobic, and topophyllic, Z′ is given by

(5)

where cot4 θ H can be obtained from the total decay-width of the resonance:Footnote 1

$$ \varGamma_{Z'} = \frac{ \alpha\cot^2\theta_H M_{Z'}}{8 \cos^2\theta_W } \biggl[ \sqrt{ 1 - \frac{4m_t^2}{M_{Z'}^2} } \biggl( 2 + 4\frac{m_t^2}{M_{Z'}^2} \biggr) + 4 \biggr]. $$
(6)

The subprocess cross section in (5) is for spin and color summing on both initial and final state legs, while most parton distributions assume spin and color averaged on the initial-state legs and spin and color summing on the final-state legs. Therefore, the subprocess cross section given by (5) must be multiplied by a factor of

$$ \biggl(\frac{1}{\mathrm{spins}} \biggr)^2 \biggl(\frac{1}{\mathrm{colors}} \biggr)^2 = \biggl(\frac{1}{2} \biggr)^2 \biggl( \frac{1}{3} \biggr)^2 = \frac{1}{36} $$
(7)

when used with parton distributions from PDFLIB [10] and other standard sources. We have taken this into account when calculating the cross section. We have also used m t =172.5 GeV/c2, and cos2 θ W =0.768. For a default parton distribution set we have chosen CTEQ6L [11]. This is a modern parton distribution set appropriate for leading-order calculations and is available in PDFLIB [10]. For a default renormalization scale we choose μ=m/2, half the \(t\bar{t}\) invariant mass. This scale has the benefit that it reduces to the usual μ=m t at top production threshold, but also increases with increasing \(t\bar{t}\) invariant mass. With these choices, the total cross section for the production of a leptophobic and topophyllic Z′ and its subsequent decay into \(t\bar{t}\) pairs is presented in Sects. 4 and 5 for the Tevatron and the LHC.

4 Cross sections at the Tevatron

We calculate numerically the lowest order cross section for the process \(p\bar{p}\rightarrow Z' \rightarrow t\bar{t}\) at the Tevatron at \(\sqrt{s} = 2\mbox{~TeV}\), using (2) and taking into account the spin-color factor in (7). The only remaining parameter of the topcolor model that affects the cross section is the mixing angle cot2 θ H , or equivalently the width Γ Z which is related to it. We calculate the cross section for different choices of Γ Z, equal to 1.2 % and 2 % of M Z, both of which qualify as narrow resonances at the Tevatron. The integration in (2) is performed using the full available phase space of \(2m_{t} < m < \sqrt{s}\). The results are tabulated in Table 1 and displayed in Fig. 1.

Fig. 1
figure 1

Cross sections at the Tevatron at \(\sqrt{s} = 2\mbox{~TeV}\), for \(\sigma_{Z'}\mathrm{B}(Z'\rightarrow t\bar{t}\,)\), with different choices of the resonance width

Table 1 Cross sections at the Tevatron at \(\sqrt{s} = 2\mbox{~TeV}\) for \(\sigma_{Z'}\mathrm{B}(Z'\rightarrow t\bar{t}\,)\) at different Z′ masses and widths

5 Cross sections at the LHC

We perform the numerical calculation of the lowest order cross section for the process \(pp \rightarrow Z' \rightarrow t\bar{t}\) at the LHC for different values of \(\sqrt{s}\) between 7–14 TeV, using (2) and taking into account the spin-color factor in (7). We calculate the cross section for different choices of Γ Z, equal to 1 %, 1.2 %, 2 %, and 10 % of M Z. The first three widths qualify as narrow resonances at the LHC, and the integration in (2) is performed using the full available phase space of \(2m_{t} < m < \sqrt{s}\). The integration for Γ Z=10 %M Z is performed using the mass interval M Z−3Γ Z<m<M Z+3Γ Z in order to sample better the cross section around the peak of the resonance. The results are tabulated in Tables 2, 3, 4 and 5, and displayed in Figs. 2, 3, 4 and 5.

Fig. 2
figure 2

Cross sections at the LHC at \(\sqrt{s} = 7\mbox{~TeV}\), for \(\sigma_{Z'}\mathrm{B}(Z'\rightarrow t\bar{t})\), with different choices of the resonance width

Fig. 3
figure 3

Cross sections at the LHC at \(\sqrt{s} = 8\mbox{~TeV}\), for \(\sigma_{Z'}\mathrm{B}(Z'\rightarrow t\bar{t})\), with different choices of the resonance width

Fig. 4
figure 4

Cross sections at the LHC at \(\sqrt{s} = 10\mbox{~TeV}\), for \(\sigma_{Z'}\mathrm{B}(Z'\rightarrow t\bar{t})\), with different choices of the resonance width

Fig. 5
figure 5

Cross sections at the LHC at \(\sqrt{s} = 14\mbox{~TeV}\), for \(\sigma_{Z'}\mathrm{B}(Z'\rightarrow t\bar{t})\), with different choices of the resonance width

Table 2 Cross sections at the LHC at \(\sqrt{s} = 7\mbox{~TeV}\) for \(\sigma_{Z'}\mathrm{B}(Z'\rightarrow t\bar{t}\,)\) at different Z′ masses and widths
Table 3 Cross sections at the LHC at \(\sqrt{s} = 8\mbox{~TeV}\) for \(\sigma_{Z'}\mathrm{B}(Z'\rightarrow t\bar{t})\) at different Z′ masses and widths
Table 4 Cross sections at the LHC at \(\sqrt{s} = 10\mbox{~TeV}\) for \(\sigma_{Z'}\mathrm{B}(Z'\rightarrow t\bar{t})\) at different Z′ masses and widths
Table 5 Cross sections at the LHC at \(\sqrt{s} = 14\mbox{~TeV}\) for \(\sigma_{Z'}\mathrm{B}(Z'\rightarrow t\bar{t})\) at different Z′ masses and widths

6 Conclusions

We have presented cross section calculations of the leptophobic topcolor Z′ decaying to \(t\bar{t}\). These calculations update the results presented in Ref. [4] for the Tevatron, by both fixing an error in the reported width of the leptophobic topcolor Z′, and using m t =172.5 GeV/c2 and CTEQ6L parton distributions in an improved calculation procedure. This note documents the first calculations of the cross section for a leptophobic topcolor Z′ at the LHC.