`ISRN High Energy PhysicsVolume 2012 (2012), Article ID 637950, 12 pagesdoi:10.5402/2012/637950`
Research Article

## The Higgs Boson: From the Lattice to LHC

P. Cea1,2 and L. Cosmai1

1Sezione di Bari, INFN, 70126 Bari, Italy
2Physics Department, University of Bari, 70126 Bari, Italy

Received 27 August 2011; Accepted 17 October 2011

Academic Editors: C. A. de. S. Pires and A. Koshelev

Copyright © 2012 P. Cea and L. Cosmai. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

#### Abstract

We discuss the triviality and spontaneous symmetry breaking scenario where the Higgs boson without self-interaction coexists with spontaneous symmetry breaking. We argue that nonperturbative lattice investigations support this scenario. Moreover, from lattice simulations, we predict that the Higgs boson is rather heavy. We estimate the Higgs boson mass (stat) (syst) GeV and the Higgs total width  GeV.

#### 1. Introduction

A cornerstone of the Standard Model is the mechanism of spontaneous symmetry breaking that, as is well known, is mediated by the Higgs boson. Then, the discovery of the Higgs boson is the highest priority of the Large Hadron Collider (LHC) [1, 2].

Usually the spontaneous symmetry breaking in the Standard Model is implemented within the perturbation theory which leads to predict that the Higgs boson mass squared, , is proportional to , where is the known weak scale (246 GeV) and is the renormalized scalar self-coupling. However, it has been conjectured since long time [3] that self-interacting four dimensional scalar field theories are trivial, namely, when ( ultraviolet cutoff). Even though no rigorous proof of triviality exists, there exist several results which leave little doubt on the triviality conjecture [47]. As a consequence, within the perturbative approach, these theories represent just an effective description, valid only up to some cut-off scale , for without a cutoff, there would be no scalar self-interactions and without them no symmetry breaking. However, within the variational Gaussian approximation, it has been suggested in [8] that this conclusion could not be true. The point is that the Higgs condensate and its quantum fluctuations could undergo different rescalings when changing the ultraviolet cutoff. Therefore, the relation between and the physical is not the same as in perturbation theory. Indeed, according to this picture, one expects that the condensate rescales as in such a way to compensate the from . As a consequence, the ratio would be a cutoff-independent constant. In other words, one should have where is a cutoff-independent constant.

It is noteworthy to point out that (1.1) can be checked by nonperturbative numerical simulations of self-interacting four dimensional scalar field theories on the lattice. Indeed, in previous studies [9, 10], we found numerical evidences in support of (1.1). Moreover, our numerical results showed that the extrapolation to the continuum limit leads to the quite simple result: pointing to a rather massive Higgs boson without self-interactions (triviality).

The plan of the paper is as follows. In Section 2, we illustrate that triviality could coexist with spontaneous symmetry breaking within the simplest self-interacting scalar field theory in four dimensions. In Section 3, we briefly review the lattice indications for the nonperturbative interpretation of triviality in self-interacting four-dimensional scalar field theories and furnish our best numerical determination of the constant in (1.1). Section 4 is devoted to discuss some experimental signatures of the Higgs boson at LHC. Finally, our conclusions are drawn in Section 5.

#### 2. Triviality and Spontaneous Symmetry Breaking

In this section, we discuss the triviality and spontaneous symmetry breaking scenario within the simplest scalar field theory, namely, a massless real scalar field with quartic self-interaction in four dimensions: where and are the bare coupling and field, respectively. As it is well known [11, 12], the one-loop effective potential is given by summing the vacuum diagrams: Integrating over and discarding a (infinite) constant give This last equation can be interpreted as the vacuum energy of the shifted field: in the quadratic approximation. Indeed, in this approximation, the hamiltonian of the fluctuation over the background is Introducing an ultraviolet cutoff , we obtain, from(2.3) It is easy to see that the one-loop effective potential displays a minimum at Moreover, so that According to the renormalization group invariance, we impose that, for , Within perturbation theory, one finds Thus, the one-loop corrections have generated spontaneous symmetry breaking. However, the minimum of the effective potential lies outside the expected range of validity of the one-loop approximation, and it must be rejected as an artefact of the approximation. On the other hand, as discussed in Section 1, there is no doubt on the triviality of the theory. As a consequence, within perturbation theory, there is no room for symmetry breaking. However, following the suggestion of [8], we argue below that spontaneous symmetry breaking could be compatible with triviality. The arguments go as follows. Write where is the bare uniform scalar condensate; thus, triviality implies that the fluctuation field is a free field with mass . This means that the exact effective potential is Moreover, the mechanism of spontaneous symmetry breaking implies that the mass of the fluctuation is related to the scalar condensate as where is some numerical constant.

Now, the problem is to see if it exists the continuum limit . Obviously, we must have Note that now we cannot use perturbation theory to determine and . As in the previous case, the effective potential displays a minimum at Using (2.15) at the minimum , we get which in turn gives This last equation implies that the theory is free asymptotically for in agreement with triviality: Inserting now (2.18) into (2.15), we obtain This last equation assures that is a renormalization group invariant. Rewriting the effective potential as we see that is manifestly renormalization group invariant.

Let us introduce the renormalized field and condensate . Since the fluctuation is a free field, we have , namely On the other hand, for the scalar condensate, according to (2.20) we have As a consequence, we get that the physical mass is finitely related to the renormalized vacuum expectation scalar field value : It should be clear that the physical mass is an arbitrary parameter of the theory (dimensional transmutation). On the other hand, the parameter being a pure number can be determined in the nonperturbative lattice approach.

#### 3. The Higgs Boson Mass

The lattice approach to quantum field theories offers us the unique opportunity to study a quantum field theory by means of nonperturbative methods. Starting from the classical Lagrangian (2.1), one obtains the lattice theory defined by the Euclidean action: where denotes a generic lattice site and, unless otherwise stated, lattice units are understood. It is customary to perform numerical simulations in the so-called Ising limit. The Ising limit corresponds to . In this limit, the one-component scalar field theory becomes governed by the lattice action with and where takes only the values or −1.

It is known that there is a critical coupling [13]: such that for the theory is in the broken phase, while, for , it is in the symmetric phase. The continuum limit corresponds to where , being the lattice spacing.

As discussed in Section 1, the triviality of the scalar theory means that the renormalized self-coupling vanishes as when . As a consequence, in the continuum limit the theory admits a Gaussian fixed point.

On the lattice, the ultraviolet cutoff is so that we have The perturbative interpretation of triviality [4, 5] assumes that, in the continuum limit, there is an infrared Gaussian fixed point where the limit corresponds to . On the other hand, according to Section 2, in the triviality and spontaneous symmetry breaking scenario, the continuum dynamics is governed by an ultraviolet Gaussian fixed point where corresponds to . As we discuss below, these two different interpretations of triviality lead to different logarithmic correction to the Gaussian scaling laws which can be checked with numerical simulations on the lattice.

In [10], extensive numerical lattice simulations of the one-component scalar field theory in the Ising limit have been performed. In particular, using the Swendsen-Wang [14] and Wolff [15] cluster algorithms, the bare magnetization (vacuum expectation value): and the bare zero-momentum susceptibility: have been computed. According to the perturbative scheme of [4, 5], one expects On the other hand, since, in the triviality and spontaneous symmetry breaking scenario, one expects that , we have The predictions in (3.8) can be directly compared with the lattice data reported in [10] and displayed in Figure 1. We fitted the data to the 2-parameter form: We obtain a rather good fit of the lattice data (full line in Figure 1) with Note that our precise determinations of the critical coupling in (3.10) are in good agreement with the value obtained in [13] (see (3.3)).

Figure 1: We show the lattice data for together with the fit (3.9) (solid line) and the two-loop fit (3.11) (dashed line) where the fit parameters and are allowed to vary inside their theoretical uncertainties (3.12).

On the other hand, the prediction based on 2-loop renormalized perturbation theory is [5, 16] (): together with the theoretical relations: We fitted the lattice data to (3.11) by allowing the fit parameters and to vary inside their theoretical uncertainties (3.12). The fit resulted in (dashed line in Figure 1) It is evident from Figure 1 that the quality of the 2-loop fit is poor. However, these results have been criticized by the authors of [16] and have given rise to an intense debate in the recent literature [1721].

Additional numerical evidences would come from the direct detection of the condensate rescaling on the lattice. To this end, we note that In Figure 2 we display the lattice data obtained in [10] for , as defined in (3.14) versus reported in [5] at the various values of . For comparison, we also report the perturbative prediction of taken from [5]. We try to fit the lattice data with Indeed, we obtain a satisfying fit to the lattice data (solid line in Figure 2):

Figure 2: The lattice data for , as defined in (3.14), and the perturbative prediction versus . The solid line is the fit to (3.15).

By adopting this alternative interpretation of triviality, there are important phenomenological implications. In fact, assuming to know the value of , the ratio is now a cutoff-independent quantity. Indeed, the physical has to be computed from the bare through rather than through the perturbative . In this case, the perturbative relation [5]: becomes obtained by replacing with in [5] and correcting for the perturbative . Using the values of reported in [5] and our values of , we display, in Figure 3, the values of as defined through (3.18) versus for GeV. The error band corresponds to a one standard deviation error in the determination of through a fit with a constant function. As one can see, the trend observed in Figure 2 compensates the from so that turns out to be a cutoff-independent constant: which corresponds to where the last error is our estimate of systematic effects.

Figure 3: The values of as defined through (3.18) versus assuming GeV. The error band corresponds to one standard deviation error in the determination of through a fit with a constant function.

One could object that our lattice estimate of the Higgs mass (3.20) is not relevant for the physical Higgs boson. Indeed, the scalar theory relevant for the Standard Model is the O(4)-symmetric self-interacting theory. However, the Higgs mechanism eliminates three scalar fields leaving as physical Higgs field the radial excitation whose dynamics is described by the one-component self-interacting scalar field theory. Therefore, we are confident that our determination of the Higgs mass applies also to the Standard Model Higgs boson.

#### 4. The Higgs Physics at LHC

Recently, both the ATLAS and CMS collaborations [22, 23] reported the experimental results for the search of the Higgs boson at the Large Hadron Collider running at TeV, based on a total integrated luminosity between 1 fb−1 and 2.3 fb−1.

It is worthwhile to briefly discuss the main physical properties of our proposal for the trivial Higgs boson. For Higgs mass in the range , the main production mechanism at LHC is the gluon fusion . The theoretical estimate of the production cross-section at LHC for centre of mass energy is [24] The gluon coupling to the Higgs boson in the Standard Model is mediated by triangular loops of top and bottom quarks. Since the Yukawa coupling of the Higgs particle to heavy quarks grows with quark mass, thus, balancing the decrease of the triangle amplitude, the effective gluon coupling approaches a nonzero value for large loop-quark masses. On the other hand, we argued that the Higgs condensate rescales with . This means that if the fermions acquire a finite mass through the Yukawa couplings, then we are led to conclude that the coupling of the physical Higgs field to the fermions could be very different from the Standard Model Higgs boson. On the other hand, the coupling of the Higgs field to the gauge vector bosons is fixed by the gauge symmetries. So the coupling of our Higgs boson to the gauge vector bosons is the same as for the Standard Model Higgs boson. For large Higgs masses, the vector-boson fusion mechanism becomes competitive to gluon fusion Higgs production [24]:

The main difficulty in the experimental identification of a very heavy Standard Model Higgs () resides in the large width which makes impossible to observe a mass peak. However, in the triviality and spontaneous symmetry breaking scenario, the Higgs self-coupling vanishes so that the decay width is mainly given by the decays into pairs of massive gauge bosons. Since the Higgs is trivial, there are no loop corrections due to the Higgs self-coupling and we obtain, for the Higgs total width where [1, 2] Assuming , , and , we obtain

A thorough discussion of the experimental signatures of our trivial Higgs is presented in [25] where we compare our proposal with the recent data from ATLAS and CMS collaborations based on a total integrated luminosity between 1 fb−1 and 2.3 fb−1. In fact, we argue that the available experimental data seem to be consistent with our scenario.

#### 5. Conclusions

The Standard Model requires the existence of a scalar Higgs boson to break electroweak symmetry and provide mass terms to gauge bosons and fermion fields. Usually the spontaneous symmetry breaking in the Standard Model is implemented within the perturbation theory which leads to predict that the Higgs boson mass squared is proportional to the self-coupling. However, there exist several results which point to vanishing scalar self-coupling. Therefore, within the perturbative approach, scalar field theories represent just an effective description valid only up to some cutoff scale, for without a cutoff, there would be no scalar self-interactions and without them no symmetry breaking. In other words, spontaneous symmetry breaking is incompatible with strictly local scalar fields in the perturbative approach.

In this paper, we have shown that local scalar fields are compatible with spontaneous symmetry breaking. In this case, the continuum dynamics is governed by an ultraviolet Gaussian fixed point (triviality) and a nontrivial rescaling of the scalar condensate. We argued that nonperturbative lattice simulations are consistent with this scenario. Moreover, we find that the Higgs boson is rather heavy. Finally, the nontrivial rescaling of the Higgs condensate suggests that the whole issue of generation of fermion masses through the Yukawa couplings must be reconsidered.

#### References

1. J. F. Gunion, H. E. Haber, G. Kane, and S. Dawson, The Higgs Hunter's Guide, Addison-Wesley, Redwood City, Calif, USA, 1990.
2. A. Djouadi, “The anatomy of electroweak symmetry breaking. Tome I: the Higgs boson in the Standard Model,” Physics Reports, vol. 457, no. 1–4, pp. 1–216, 2008.
3. K. G. Wilson and J. Kogut, “The renormalization group and the $\epsilon$ expansion,” Physics Reports, vol. 12, no. 2, pp. 75–199, 1974.
4. M. Lüscher and P. Weisz, “Scaling laws and triviality bounds in the lattice φ4 theory. (I). One-component model in the symmetric phase,” Nuclear Physics, vol. 290, no. C, pp. 25–60, 1987.
5. M. Lüscher and P. Weisz, “Scaling laws and triviality bounds in the lattice ${\varphi }^{4}$ theory. (II). One-component model in the phase with spontaneous symmetry breaking,” Nuclear Physics, vol. 295, no. 1, pp. 65–92, 1988.
6. R. Fernandez, J. Fröhlich, and A. D. Sokal, Random Walks, Critical Phenomena, and Triviality in Quantum Field Theory, Springer, Berlin, Germany, 1992.
7. C. B. Lang, Computer Stochastics in Scalar Quantum Field Theory, arXiv:hep-lat/9312004v1, 1993.
8. M. Consoli and P. M. Stevenson, “The non-trivial effective potential of the 'trivial' λΦ4 theory: a lattice test,” Zeitschrift für Physik C, vol. 63, no. 3, pp. 427–436, 1994.
9. P. Cea, M. Consoli, and L. Cosmai, “Indications on the Higgs boson mass from lattice simulations,” Nuclear Physics B - Proceedings Supplements, vol. 129-130, pp. 780–782, 2004.
10. P. Cea, M. Consoli, and L. Cosmai, “Large rescaling of the Higgs condensate: theoretical motivations and lattice results,” Nuclear Physics B - Proceedings Supplements, vol. 83-84, no. 1–3, pp. 658–660, 2000.
11. S. Coleman and E. Weinberg, “Radiative corrections as the origin of spontaneous symmetry breaking,” Physical Review D, vol. 7, no. 6, pp. 1888–1910, 1973.
12. R. Jackiw, “Functional evaluation of the effective potential,” Physical Review D, vol. 9, no. 6, pp. 1686–1701, 1974.
13. D. S. Gaunt, M. F. Sykes, and S. McKenzie, “Susceptibility and fourth-field derivative of the spin-1/ 2 Ising model for T>Tc and d=4,” Journal of Physics A: General Physics, vol. 12, no. 6, article 018, pp. 871–877, 1979.
14. R. H. Swendsen and J.-S. Wang, “Nonuniversal critical dynamics in Monte Carlo simulations,” Physical Review Letters, vol. 58, no. 2, pp. 86–88, 1987.
15. U. Wolff, “Collective monte Carlo updating for spin systems,” Physical Review Letters, vol. 62, no. 4, pp. 361–364, 1989.
16. J. Balog, A. Duncan, R. Willey, F. Niedermayer, and P. Weisz, “The 4d one component lattice φ4 model in the broken phase revisited,” Nuclear Physics B, vol. 714, no. 3, pp. 256–268, 2005.
17. P. Cea, M. Consoli, and L. Cosmai, Large Logarithmic Rescaling of the Scalar Condensate: A Subtlety with Substantial Phenomenological Implications, arXiv:hep-lat/0501013v1, 2005.
18. P. M. Stevenson, “Comparison of perturbative RG theory with lattice data for the 4d Ising model,” Nuclear Physics B, vol. 729, no. 3, pp. 542–557, 2005.
19. J. Balog, F. Niedermayer, and P. Weisz, “Repairing Stevenson's step in the 4d Ising model,” Nuclear Physics B, vol. 741, no. 3, pp. 390–403, 2006.
20. P. Castorina, M. Consoli, and D. Zappalà, “An alternative heavy Higgs mass limit,” Journal of Physics G: Nuclear and Particle Physics, vol. 35, no. 7, Article ID 072010, 2008.
21. P. H. Lundow and K. Markstrom, “private communication,” 2009.
22. A. Nisati, “Higgs searches at ATLAS,” in Proceedings of the 25 International Symposium on Lepton Photon Interactions at High Energies, Mumbai, India, August 2011.
23. V. Sharma, “Higgs searches at CMS,” in Proceedings of the 25 International Symposium on Lepton Photon Interactions at High Energies, Mumbai, India, August 2011.
24. S. Dittmaier, Handbook of LHC Higgs Cross Sections: 1. Inclusive Observables, arXiv:1109.5922, 2011.
25. P. Cea and L. Cosmai, The Trivial Higgs at LHC, arXiv:1101.0593v3, 2011.