discuss a serious problem related to the Higgs mechanism and show that the unitary gauge which imposes the condition of ф=ф ÷ on the Higgs fields does not correspond to a proper gauge fixing. Instead, this is simply a procedure for producing the massive vector boson fields by hand. This suggests that the Lagrangian density of the weak interactions should be reconsidered by starting from the massive vector boson fields which couple to the fermion currents as the initial ingredients. Here, it is shown that the new renormalization scheme with massive vector bosons has no intrinsic problem and the massive vector boson fields do not give rise to any divergences for the physical observables in the renormalization scheme.
The whole idea of the symmetry breaking has been critically examined in the recent textbook [
The most important point of the spontaneous symmetry breaking physics is that the symmetry breaking is only related to the property of the vacuum state. The Lagrangian density should keep the chiral symmetry all the time, but the state may violate the symmetry if the state with broken symmetry is lower than the state that preserves the symmtry.
In this respect, one cannot discuss its physics by rewriting the Lagrangian density into a new shape. As one knows, the property of the vacuum state should be determined from the eigenstate of the total Hamiltonian in the corresponding field theory model. Therefore, the physics of the Higgs mechanism [
As we will show below, the whole procedure of the Higgs mechanism cannot be justified at all. This is mainly connected to the misunderstanding of the gauge fixing where one degree of freedom of the gauge fields must be reduced in order to solve the equations of motion of the gauge fields. Therefore, one cannot insert the condition of the gauge fixing into the Lagrangian density. This is clear since the Lagrangian density only plays a role for producing the equation of motions. Indeed, the Lagrangian density itself is not directly a physical observable, and the Hamiltonian constructed from the Lagrangian density is most important after the fields are quantized. For the field quantization, one has to make use of the gauge fixing condition which can determine the gauge field together with the equation of motions. This means that only the final Lagrangian density is relevant to the description of physical observables, and thus the success of the Glashow-Weinberg-Salem model [3-5] is entirely due to the final version of the weak Hamiltonian which is not at all the gauge field theory but is a model field theory of the massive vector fields which couple to the fermion currents.
In this respect, it is very important to examine the renormalizability of the final version of the weak Hamiltonian. Here, we show that the renormalizability of the model field theory can be indeed justified. This is basically due to the fact that there is no divergence in the vertex corrections of fermions due to the massive vector boson propagations once we employ a proper propagator of the massive vector bosons. Here, we briefly review how we can obtain the new propagator of the massive vector boson, and the correct shape of the propagator of the massive vector bosons should be given as [
This shape is determined by solving the equations of motion for the massive vector bosons. As long as we employ the above propagator, we find that the anomalous magnetic moment of electron due to weak bosons does not have any divergences and it is indeed very small number which is consistent with experiment. Thus, one can see that the physical observables with the massive vector boson propagations are all finite and that there are niether conceptual nor technical problems in the renormalization scheme of the massive vector bosons interacting with fermions.
Now we discuss the basic problem of the Higgs mechanism. The Lagrangian density of the Higgs mechanism is given as
where
Here, we only consider the U(1) case since it is sufficient for the present discussions. The above Lagrangian density is indeed gauge invariant, and in this respect, the scalar field may interact with gauge fields in equation (2.1). However, it should be noted that there is no experimental indication that the fundamental scalar field can interact with any gauge fields in terms of the Lagrangian density of equation (2.1).
The equations of motion for the scalar field become
On the other hand, the equation of motion for the gauge field can be written as
where
One can also check that the current is conserved, that is
This Lagrangian density of equation (2.1) has been employed for the discussion of the Higgs mechanism.
Now, we should count the number of the degrees of freedom and the number of equations. For the scalar field, we have two independent functions and. Concerning the gauge fields, we have four since there are, , , fields. Thus, the number of the independent fields is six. On the other hand, the number of equation is five since the equation for the scalar fields is two and the number of the gauge fields is three. This three can be easily understood, even though it looks that the independent number of equations in equation (2.5) is four, but due to the current conservation the number of the independent equations becomes three. This means that the number of the independent functions is six while the number of equations is five, and they are not equal. This is the gauge freedom, and therefore in order to solve the equations of motion, one has to put an additional condition for the gauge field like the Coulomb gauge which means. In this respect, the gauge fixing is simply to reduce the redundant functional variable of the gauge field to solve the equations of motion, and nothing more than that.
In the Higgs mechanism, the central role is played by the gauge fixing of the unitary gauge. The unitary gauge means that one takes
This is the constraint on the scalar field even though there is no gauge freedom in this respect. For the scalar field, the phase can be changed, but this does not mean that one can erase one degree of freedom. One should transform the scalar field in the gauge transformation as
but one must keep the number of degree of freedom after the gauge transformation. Whatever one fixes the gauge, one cannot change the shape of the scalar field since it is a functional variable and must be determined from the equations of motion. The gauge freedom is, of course, found in the vector potential as we discussed above. In this sense, one sees that the unitary gauge fixing is a simple mistake. The basic reason why people overlooked this simple-minded mistake must be due to their obscure presentation of the Higgs mechanism. Also, it should be related to the fact that, at the time of presenting the Higgs mechanism, the spontaneous symmetry breaking physics was not understood properly since the vacuum of the corresponding field theory was far beyond the proper understanding. Indeed, the Goldstone boson after the spontaneous symmetry breaking was taken to be almost a mysterious object since there was no experiment which suggests any existence of the Goldstone boson. Instead, a wrong theory prevailed among physicists. Therefore, they could assume a very unphysical procedure of the Higgs mechanism and people pretended that they could understand it all.
After an improper gauge fixing, one arrives at the final Lagrangian density
where we rewrite the Higgs field as
Since the real scalar field is supposed to be small and besides a real scalar field is unphysical [7,8], it may be set to zero, that is,. In this case, we arrive at the following Lagrangian density
This should be the final Lagrangian density of the Higgs theory, and it is nothing but the massive vector boson field which has nothing to do with the gauge theory.
For the equations of motion equations (2.3)-(5), one can make a proper gauge fixing such as the Coulomb gauge () or the temporal gauge (). In this case, one can solve the equations of motion properly, and one can calculate any physical observables which are, in this case, gauge invariant quantities like in the classical field theory. Further, we can quantize the fields and after the gauge fixing, and we can carry out the perturbation theory since we have now the quantized Hamiltonian. But this must be completely different from the Higgs mechanism.
In the Lagrangian density of the Higgs mechanism, one assumes a self-interacting field potential
This was originally introduced in the discussion of the spontaneous symmetry breaking physics as a toy model [
In 1970’s, people found that some experiments indicate there might be heavy vector bosons exchanged between leptons and baryons in the weak processes. Therefore, people wanted to start from the massive vector bosons. However, it was somehow believed among educated physicists that only gauge field theories must be renormalizable. We do not know where this belief came from. In fact, there is no strong reason that only the gauge field theory is renormalizable. It is clear that QED is a gauge theory which is renormalizable, and there is no conceptual problem in QED. At the present stage, one can say that QED can describe most of the experiments related to the electromagnetic processes, except that the Lamb shift treatment is not satisfactory [
However, one should be careful for the renormalizability of the non-abelian gauge field theory. As one can easily convince oneself, the non-abelian gauge theory has an intrinsic problem of the perturbation theory [
Even though the Higgs mechanism itself has an intrinsic problem, the final Lagrangian density may well be physically interesting. This is clear since, from this Lagrangian density, one can construct the Hamiltonian which can describe the experimental observables. In this respect, we may write the simplest Lagrangian density for two flavor leptons which couple to the SU(2) vector fields
where denotes the mass of the vector boson. The fermion wave function has two components
Correspondingly, the mass matrix can be written as
The fermion current and the field strength are defined as
This Lagrangian density is almost the same as the standard model Lagrangian density, apart from the Higgs fields.
Therefore, it should be important to examine whether the renormalization scheme of the massive vector bosons interacting with fermions can be justified or not [
Here, we briefly review the derivation of the new propagator of the massive vector boson which has recently been evaluated properly in terms of the polarization vector [
This is quite important since this does not generate any quadratic divergences in the self-energy diagrams of fermions any more while the old propagator in the textbooks gives rise to the quadratic divergence [1,12].
Here, we briefly explain how we can obtain equation (4.1). The free Lagrangian density for the vector field with its mass is written as
with. In this case, the equation of motion becomes
Since the free massive vector boson field should have the following shape of the solution
we can insert this solution into equation (4.2) and obtain the following equation for the polarization vector
The condition that there should exist a non-zero solution for the requires that the determinant of the matrix should be zero, namely
This equation can be easily solved, and we find the following equation
which is the only physical solution of equation (4.5). Therefore we insert this solution into equation (4.4) and obtain the equation for the polarization vector
which should always hold. Here, we should note that this process of determining the condition on the wave function of is just the same as solving the free Dirac equation. Obviously this is the most important process of determining the wave functions in quantum mechanics, and surprisingly, this has been missing in the treatment of determining not only the massive vector boson propagator but also the photon propagator as well. Also, one can notice that the condition of equation (4.7) is just the same as the Lorentz gauge fixing condition in quantum electrodynamics (QED), and this is often employed as the gauge fixing. However, one sees by now that the Lorentz condition itself can be obtained from the equation of motion, and therefore it is more fundamental than the gauge fixing, even though the theory of massive bosons has no gauge freedom. This indicates that the Lorentz gauge fixing in QED should not be a proper gauge fixing procedure since the Lorentz gauge fixing cannot give a further constraint on the polarization vector in the perturbation theory of QED. In addition, the number of degrees of freedom for the gauge field can be understood properly since photon must have the two degrees of freedom due to the two constraint equations (the Lorentz condition and the gauge fixing condition).
Now, we can evaluate the propagator of the massive vector field in the S-matrix expression. The second order perturbation of the S-matrix for the bosonic part can be written in terms of the T-product of the boson fields and it becomes
After the summation over the polarization states, we find the following shape for as
which satisfies the Lorentz invariance and the condition of the polarization vector. One sees that this is the only possible solution. From equation (4.9), one finds that the right propagator of the massive vector boson should be the one given in equation (4.1). Here it may be important to note that the polarization vector should depend only on the four momentum, and it cannot depend on the boson mass at this expression. Later, one may replace the term by in case the vector boson is found at the external line. But in the propagator, the replacement of the term by is not allowed.
Now we can calculate the vertex correction of electromagnetic interaction due to the boson. This is a physical process which can be directly related to the physical observables, and therefore we should be concerned with its divergences. The vertex correction can be written by evaluating the corresponding Feynman diagrams as [
First, we show that the apparent logarithmic divergent terms in equation (5.1) vanish to zero, and this can be easily proved since we can find
where. Therefore, there is no logarithmic divergence for the vertex correction from the weak massive boson propagations. This is very important in that the physical processes do not have any divergences when we make use of the massive boson propagator of equation (4.1).
Now we should calculate the electron by boson propagation. This is just the finite part of the vertex correction due to the boson, and it is calculated to be
where. Therefore, the electron should be modified to
which is a very small effect, and it is indeed consistent with experiment of electron. We should note that, if we employed the old but standard propagator of the massive vector boson as given in the textbooks [
The intrinsic problem of the Higgs mechanism is discussed in terms of the gauge fixing condition. This is also related to the understanding of the spontaneous symmetry breaking physics. Here, we have shown that the Higgs mechanism cannot be justified since the gauge invariance of the Lagrangian density is violated by hand. However, we believe that the final version of the weak Hamiltonian should be correct, and therefore we have discussed the renormalization scheme of the massive vector bosons. Here, we have shown that the vertex corrections do not have any divergences as long as we employ the proper propagators of massive vector bosons. Therefore we can calculate physical observables without worrying about the renormalization procedures in the weak interaction model Hamiltonian with the massive vector boson fields.
The basic reason why the standard model Hamiltonian becomes a reasonable model is due to the fact that they make mistakes twice and thus it gets back to the right Hamiltonian which can describe the nature. The first mistake is related to the non-abelian character of the gauge field theory model. As one knows, the SU(2) charge is gauge dependent, and therefore it cannot be a physical observable. Thus, it is impossible to develop the perturbation theory since the unperturbed Hamiltonian is gauge dependent. The second mistake is concerned with the breaking of the local gauge invariance in terms of Higgs mechanism, and it is, of course, an incorrect treatment as we have shown in this paper.
In this respect, as long as we carefully examine the renormalization scheme of the field theory models, we can say that the massive vector fields do not give rise to any difficulties in the renormalization scheme. However, the basic difficulty of the renormalization scheme should be concerned with the massless nature of the gauge field in QED. Indeed, as one knows, the vertex corrections of fermions due to photon propagations contain an infra-red divergence [