We address the effect of a quantum gravity induced minimal length on a physical observable for three-dimensional Yang-Mills. Our calculation is done within stationary perturbation theory. Interestingly enough, we find an ultraviolet finite interaction energy, which contains a regularized logarithmic function and a linear confining potential. This result highlights the role played by the new quantum of length in our discussion.
1. Introduction
It is known that one of the main unsolved problems in high energy physics is a quantitative description (from first principles) of confinement in quantum chromodynamics (QCD). Albeit phenomenological models still represent a key tool for understanding confinement physics. In this context we recall the phenomenon of condensation, where in the scenario of dual superconductivity, it is conjectured that the QCD vacuum behaves as a dual-type II superconductor. More explicitly, due to the condensation of magnetic monopoles, the chromoelectric field acting between qq¯ pair is squeezed into strings, and the nonvanishing string tension represents the proportionality constant in the linear potential. Incidentally, lattice calculations have confirmed this picture by showing the formation of tubes of gluonic fields connecting colored charges [1].
It is also known that considerable attention has been paid to the investigation of extensions of the standard model (SM), such as Lorentz invariance violation and fundamental length [2–7], because the SM does not include a quantum theory of gravitation. In this respect we recall that, in the last few years, the emphasis of quantum gravity has been on effective models incorporating a minimal length scale. In fact, there are several approaches on how to incorporate a minimal length scale in a quantum field theory, leading to a model of quantum space-time [8–11]. Of these, noncommutative quantum field theories have motivated a great interest [12–17]. Notice that this noncommutative geometry is an intrinsic property of space-time. In addition, we also recall that most of the known results in the noncommutative approach have been achieved using a Moyal star-product. Nevertheless, in recent times, a new formulation of noncommutative quantum field theory in the presence of a minimal length has been proposed in [18–20]. Afterwards, this approach was further developed by the introduction of a new multiplication rule, which is known as Voros star-product. Notwithstanding, physics turns out be independent from the choice of the type of product [21]. Consequently, with the introduction of noncommutativity by means of a minimal length, the theory becomes ultraviolet finite and the cutoff is provided by the noncommutative parameter θ.
In this perspective the present work is an extension of our previous study [22]. Thus, the basic ideas underlying the analysis of this paper are derived from our earlier paper [22]. Specifically, in this work we will focus attention on the impact of a minimal length on a physical observable for pure Yang-Mills theory in (2+1)D. It is worth noting here that Yang-Mills theories in (2+1)D are very relevant for a reliable comparison between results coming from continuum and lattice calculations [23]. Also, (2+1)D theories have been raising a great deal of interest in connection with branes activity, for example, issues like self-duality [24] and new possibilities for supersymmetry breaking as induced by 3-branes [25]. Yet, (2+1)D theories may be adopted to describe the high-temperature limit of models in (3+1)D [26]. In fact, such theories are of interest to probe low-dimensional condensed matter systems, such as spin or pairing fluctuations by means of effective gauge theories, for which (2+1)D theories are a very good approximation [27]. Thus, in order to accomplish the purpose of studying the impact of a minimal length for Yang-Mills theory in (2+1)D, we will work out the static potential for the case under consideration. As we will see, the presence of a minimal length leads to an ultraviolet finite static potential, which contains a regularized logarithmic function and a linear confining potential. Accordingly, our study offers a straightforward calculation in which some features of three-dimensional nonabelian gauge theories become more transparent.
2. Interaction Energy
We will now discuss the interaction energy for Yang-Mills theory in the presence of a minimal length. We start then with the three-dimensional space-time Lagrangian:
(1)L=-14Tr(FμνFμν)=-14FμνaFaμν.
Here Aμ(x)=Aμa(x)Ta and Fμνa=∂μAνa-∂νAμa+gfabcAμbAνc, with fabc the structure constants of the gauge group.
As we have indicated in [22], our analysis is based in perturbation theory along the lines of [28–30]. To do this, we will work out the vacuum expectation value of the energy operator H(〈0|H|0〉) at lowest order in g, in the Coulomb gauge. The canonical Hamiltonian can be worked as usual and is given by
(2)H=12∫d2x{(ETa)2+(Ba)2-ϕa∇2ϕa},
where the color-electric field Ea has been separated into transverse and longitudinal parts: Ea=ETa-∇ϕa.
Next, by making use of Gauss’s law
(3)∇2ϕa=g(ρa-fabcAb·Ec),
we get
(4)∇2ϕa=(gδap+g2fabpAb·∇1∇2+g3fabcAb·∇1∇2fchpAh·∇1∇2)×(ρp-fpdeAd·ETe).
Following our earlier procedure, the corresponding formulation of this theory in the presence of a minimal length is by means of a smeared source [22, 31, 32]. Thus, we will take the sources as ρa≡ρ1a+ρ2a=ρq¯a+ρqa, where ρq¯a(x)=tq¯ae(θ/2)∇2δ(3)(x-y′) and ρqa(x)=tqae(θ/2)∇2δ(3)(x-y), where tq¯a and tqa are the color charges of a heavy antiquark q¯i and a quark qi in a normalized color singlet state |Ψ〉=N-1/2|qi〉|q¯i〉. Hence tqatq¯a=(1/N)tr(TaTa)=-CF, where the anti-Hermitian generators Ta are in the fundamental representation of SU(N).
By proceeding in the same way as in [22], we obtain the expectation value of the energy operator H to order g2 and g4:
(5)V=V1+V2,
where
(6)V1=-g2∫d2x〈0|ρ1a1∇2ρ2a|0〉,(7)V2=-3g4fabcfchq∫d2x〈0|ρ1a1∇2Ab·∇1∇2Ah·∇1∇2ρ2q|0〉.
The V1 term is exactly the one obtained in [32]. Consequently, (6) takes the form
(8)V1=-g2CF∫d2k(2π)2e-θk2k2e-ik·r=g2CF2π{ln(μr)-e-r2/4θln(r2θ)},
with |r|≡|y-y′|=r and μ is an infrared regulator. Again, as in our previous analysis [32], unexpected features are found. Interestingly, it is observed that, unlike the Coulomb potential which is singular at the origin, V1 is finite there: V1=(g2CF/2π)ln(2μθ).
We now turn our attention to the V2 term, which is given by
(9)V2=3g4CACF∫d2k(2π)2e-θk2k2e-ik·rI(k),
where
(10)I(k)=∫d2p(2π)212|p|(p-k)2(1-(p·k)2p2k2).
In passing we recall that to obtain (9) we have expressed the Aai-fields in terms of a normal mode expansion: Aai(x,t)=∫(d3p/(2π)32wp)∑λεi(p,λ)[aa(p,λ)e-ipx+a†a(p,λ)eipx], along with [aa(p,λ),a†b(l,σ)]=δabδλσδ(3)(p-l) and ∑λεi(k,λ)εj(k,λ)=δij-kikj/k2. Here we would mention that the correction term of order g4 represents an antiscreening effect. Incidentally, it is of interest to notice that precisely this term is in the origin of asymptotic freedom in the (3+1)D case, which is due to the instantaneous Coulomb interaction of the quarks.
When the integral (10) is performed, one gets
(11)I(k)=18π21|k|(-1.5706+π2).
Expression (9) then becomes
(12)V2=-38π2(1.5706-π2)g4CACF∫d2k(2π)2e-θk2|k|3e-ik·r.
We now proceed to calculate the integral (12). Following our earlier procedure [32], (12) is further rewritten as
(13)I≡limε→0I~=limε→0(μ2)-ε/2∫d2+εk(2π)2e-θk2|k|3eik·r=limε→0(μ2)-ε/2Γ(3/2)∫0∞dxx1/2∫d2+εk(2π)2e-(θ+x)k2eik·r.
Then, the I term takes the form
(14)I=limε→0(μ2)-ε/2(r2)-ε/2Γ(3/2)(π)1+ε/2×14∫0r2/4θdττε/2-1e-τ(r24τ-θ)1/2.
Hence, at leading order in θ, (14) reduces to
(15)I=-12(π)3/2{rγ(12,r24θ)+2θe-r2/4θ+θrγ(12,r24θ)},
where γ(1/2,r2/4θ) is the lower incomplete Gamma function defined by the following integral representation:
(16)γ(ab,x)≡∫0xduuua/be-u.
Accordingly, the V2 term reads
(17)V2=316π7/2(1.5706-π2)g4CACF×{rγ(12,r24θ)+2θe-r2/4θ+θrγ(12,r24θ)}.
Now we focus on the (g4) screening contribution to the potential, which is due to the exchange of transverse gluons. From our above perturbation theory, we find that V2* is given by
(18)V2*=2g4fabcfdef∑n=2gluon1En∫d3x∫d3w〈0|ρ2a1∇2Ab·ETc|n〉x×〈n|ρ1d1∇2Ae·ETf|0〉w.
In passing we recall that 〈0|ρ2a(1/∇2)Ab·ETc|n〉 is the matrix element in the basis of states in which the nonperturbated Hamiltonian is diagonal. Next, it should be noted that the intermediate state |n〉 must contain a pair of transverse gluons, since the terms Ab·ETc must create and destroy dynamical gluon pairs. We can, therefore, write two gluon states as
(19)∑n=2gluon|n〉〈n|=12∑kl∑λσ∫d3k∫d3la†e(k,λ)a†f(l,σ)|0〉〈0|×af(l,σ)ae(k,λ).
By substituting (19) into (18) and following our earlier procedure, the V2* term assumes the form
(20)V2*=-CACFg4∫d2k(2π)2e-θk2k4eik·rI(k),
where
(21)I(k)=∫d2l(2π)2(|l|-|l-k|)24|l||l-k|(|l|+|l-k|)×(1-k2(l-k)2+(k·l)2(l-k)2l2).
Integrating now over l, one then obtains I(k)=|k|((1/2π)(15/16)-(1/8)+(3/32π2)). As a consequence, the V2* term becomes
(22)V2*=-(12π1516-18+332π2)g4CACF∫d2k(2π)2e-θk2|k|3e-ik·r.
It is straightforward to see that this integral is exactly the one obtained in expression (12).
By putting together (8), (12), and (22), we evaluate the interquark potential in position space. We thus finally obtain
(23)V(r)=g2CF2π{ln(μr)-e-r2/4θln(r2θ)}+g4CACF2(π)3/20.165×{rγ(12,r24θ)+2θe-r2/4θ+θrγ(12,r24θ)},
which is ultraviolet finite (Figure 1). An immediate consequence of this is that for θ=0 one obtains the known interquark potential at order g4 [30]. Note that in Figure 1, for illustrative purposes, we have defined g2CF/2π=1, g4CACF/2(π)3/2=1, μ=1, and θ=1.4.
The potential V, as a function of x=r/2θ.
3. Conclusion
To conclude, let us put our work in its proper perspective. As already anticipated, this work is a sequel to [22], where we have considered a three-dimensional extension of the recently (3+1)D calculation in the presence of a minimal length. To do this, we have exploited a correct identification of field degrees with observable quantities. Once the identification has been made, the computation of the potential is achieved by means of Gauss’ law. Interestingly enough, it was found that the static potential profile is ultraviolet finite, which contains a regularized logarithmic function and a linear potential leading to confinement of static sources. Finally, we note that our results agree for the θ=0 case with the calculation shown in [30]. Also very recently, in the context of the Georgi-Glashow model it has been shown that there is confinement at distances much larger than the screening length [33]. Since our calculation has shown that there is confinement in three-dimensional Yang-Mills, it seems a challenging work to extend the above analysis to the Georgi-Glashow model. We expect to report on progress along these lines soon.
Conflict of Interests
The author declares that there is no conflict of interests regarding the publication of this paper.
Acknowledgments
The author would like to thank José A. Helayël-Neto for useful discussions. This work was partially supported by Fondecyt (Chile) Grant no. 1130426. The author also wishes to thank the Field Theory Group of the CBPF for hospitality and PCI/MCT for support.
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