Using the AdS/CFT correspondence, we investigate the Schwinger effect in a confining D3-brane background with chemical potential. The potential between a test particle pair on the D3-brane in an external electric field is obtained. The critical field Ec in this case is calculated. Also, we apply numerical method to evaluate the production rate for various cases. The results imply that the presence of chemical potential tends to suppress the pair production effect.
Ministry of Science and Technology of China2015CB856904(4)NSFC11547204NSFC11475149NSFC11375070112215041. Introduction
Schwinger effect is known as the pair production in an external electric field in QED [1]. The virtual electron-position pairs can become real particles when a strong electric field is applied. The production rate Γ has been calculated in the weak-coupling and weak-field approximation long time ago. Later, it is generalized to arbitrary-coupling and weak-field case in [2](1)Γ∝e-πm2/eE+e2/4,where m and e are the mass and charge of the created particles, respectively, E is the external electric field. This nonperturbative effect can be explained as a tunneling process and is not restricted to QED but usual for QFTs coupled to U(1) gauge field.
AdS/CFT, namely, the duality between type IIB superstring theory formulated on AdS5×S5 and N=4 SYM in four dimensions, can realize a system that coupled with U(1) gauge field [3–5]. Therefore, it is very interesting to consider the Schwinger effect in a holographic setup. After the works [6, 7] in which the creation rate of the quark pair in N=4 SYM theory was obtained firstly, there are many attempts to address Schwinger effect in this direction. For instance, the universal aspects of this effect in the general backgrounds are investigated in [8]. The pair production in confining background is studied in [9, 10]. The potential barrier for the pair creation is analyzed in [11]. The pair production in the conductivity of a system of flavor and color branes is analyzed in [12]. The Schwinger effect with constant electric and magnetic fields is investigated in [13, 14]. The nonrelativistic Schwinger effect is discussed in [15]. The Gauss-Bonnet corrections to this effect are studied in [16]. This effect is also studied with some AdS/QCD models [17, 18]. Other important results can be found, for example, in [19–24]. For a recent review on this topic, see [25].
As we know, a finite temperature of the gauge theory is on the gravity side of the duality represented by a black hole horizon in the bulk located at rt in the fifth coordinate and extended in the other four space-time directions. In addition, a chemical potential of the gauge theory can be obtained in this setup by giving the black hole an electric charge. Since the Schwinger effect in a confining D3-brane background has been discussed in [9], it is interesting to consider the influence of the chemical potential on Schwinger effect in this case. In this paper, we will add the chemical potential to the confining D3-brane background. We would like to see how chemical potential affects the Schwinger effect. It is the motivation of the present work.
The organization of this paper is as follows. In the next section, the background with chemical potential is briefly introduced. In Section 3, we perform the potential analysis in this background. Then we investigate the production rate in Section 4. The last part is devoted to conclusion and discussion.
2. Background with Chemical Potential
In the framework of the AdS/CFT duality, N=4 SYM theory with a chemical potential is obtained by making the black hole in the holographic dimension be charged. The corresponding metric is an asymptotical AdS5 space with a Reissner-Nordstrom black hole. Its metric can be written as [26](2)ds2=r2L2-dx02+dx12+dx22+frdx32+L2r2fr-1dr2+L2dΩ52,with(3)fr=1-1+Q2rtr4+Q2rtr6,where L is the AdS space radius, the string tension 1/2πα′ relates the ’t Hooft coupling constant by L2/α′=λ and r denotes the radial coordinate of the black brane geometry. rt is the inverse compactification radius in x3-direction. As rt grows, the radius shrinks.
The chemical potential μ is given by(4)μ=3QrtL2,where the charge Q of the black hole is in the range 0≤Q≤2.
Note that when Q=0 (zero chemical potential), the usual confining D3-brane background is reproduced. In addition, when rt=0 (zero temperature), the usual AdS5×S5 background is reproduced.
We should point out that the chemical potential implemented in this way is not the quark (or baryon) chemical potential of QCD but a chemical potential that refers to the R-charge of N=4 SYM theory. However, we can apply it as a simple way of introducing finite density effects into the system in the present work. More discussions about the AdS-RN in the context of holographic setups can be found in [27, 28].
3. Potential Analysis3.1. Potential Research
We now perform the potential analysis for confining D3-brane background with chemical potential using the metric equation (2). The classical string action can reduce to the Nambu-Goto action(5)S=TF∫d2σg=TF∫dτdσL,TF=12πα′,where g is the determinant of the induced metric on the string world sheet embedded in the target space; that is,(6)gαβ=gμν∂Xμ∂σα∂Xν∂σβ,where Xμ and gμν are the target space coordinates and the metric and σα with α=0,1 parameterize the world sheet.
By using the static gauge,(7)x0=τ,x1=σ,r=rσ,we can obtain the induced metric gαβ:(8)g00=r2L2,g01=g10=0,g11=r2L2+L2r21-1+Q2rt/r4+Q2rt/r6∂r∂σ2.
Then the Lagrangian density becomes(9)L=11-1+Q2rt/r4+Q2rt/r6r˙2+r4L4,with r˙=dr/dσ.
Now that L does not depend on σ explicitly, we have the conserved quantity,(10)L-∂L∂r˙r˙.
The boundary condition at σ=0 is(11)r˙=0,r=rcrt<rc<r0,which leads to(12)r41/1-1+Q2rt/r4+Q2rt/r6r˙2+r4/L4=C=rc2L2;then a differential equation is derived,(13)r˙=drdσ=r2r4-rc4rc2L21-1+Q2rtr4+Q2rtr6.
By integrating (13) the separate length x of the test particle pair on the D3-brane becomes(14)x=2L2r0a∫11/adyy2y4-11-1+Q2b/ay4+Q2b/ay6,where the following dimensionless parameters have been introduced:(15)y≡rrc,a≡rcr0,b≡rtr0.
Plugging (13) into (9), one obtains the classical action. Then the sum of potential energy (PE) and static energy (SE) of string is obtained as(16)VPE+SE=2TFr0a∫11/ay2dyy4-11-1+Q2b/ay4+Q2b/ay6.
3.2. The Critical Field
To ensure that the potential analysis is right and consistent with the DBI result, we should pause here to gain the critical field by DBI action at hand.
The DBI action is(17)SDBI=-TD3∫d4x-detGμν+Fμν,where TD3 is the D3-brane tension:(18)TD3=1gs2π3α′2.
In terms of the metric equation (2), the induced metric Gμν reads(19)G00=-r2L2,G11=r2L2,G22=r2L2,G33=r2L21-1+Q2rtr4+Q2rtr6=r2L2fr.
After considering Fμν term, which can be written as Fμν=2πα′Fμν [29], we find(20)Gμν+Fμν=-r2L22πα′E12πα′E22πα′E3-2πα′E1r2L200-2πα′E20r2L20-2πα′E300r2L2fr,which leads to(21)detGμν+Fμν=-r4L4frr4L4-2πα′2E12+E22+E32fr.
Here the electric field is only turned on x1-direction [9]; one can take E2=E3=0 in (21), which yields (22)detGμν+Fμν=-r4L4frr4L4-2πα′2E2,where we have replaced E1 by E for simplification.
Plugging (22) into (17) and making the D3-brane be located at r=r0, we have(23)SDBI=-TD3r04L4∫d4xfr1-2πα′2L4r04E2.
To avoid the action equation (23) being ill-defined, it is required that(24)1-2πα′2L4r04E2≥0,where we have used the assumption(25)fr≥0.
So the range of electric field is(26)E≤12πα′r02L2.
Finally, the critical field Ec in confining D3-brane background with chemical potential is obtained; that is,(27)Ec=12πα′r02L2.
Note that Ec is not affected by the chemical potential. In other words, the critical field Ec in this case is consistent with that in confining D3-brane background.
3.3. Total Potential
To proceed, we compute the total potential. For convenience, we introduce a dimensionless parameter(28)α≡EEc.
Then, from (14) and (16), the total potential Vtot can be written as(29)Vtot=VPE+SE-Ex=2TFr0a∫11/ay2dyy4-11-1+Q2b/ay4+Q2b/ay6-2TFαr0a∫11/adyy2y4-11-1+Q2b/ay4+Q2b/ay6.
We have checked that the total potential Vtot in confining D3-brane background can be derived from (29) if we neglect the effect of chemical potential by plugging Q=0 in (29).
Before discussing the results, let us recall the potential analysis in confining D3-brane background. There exist two critical values of the electric field, Es=TFrt2/L2 and Ec=TFr02/L2. When E<Es, the pair is confined and no Schwinger effect can occur. When Es<E<Ec, the potential barrier is present and the pair production is described as a tunneling process. As E increases, the potential barrier decreases gradually. At last, it vanishes at E=Ec. When E>Ec, no tunneling occurs and the production rate is not exponentially suppressed any more, the pair production is catastrophic, and the vacuum becomes totally unstable.
We now discuss the results. The total potential can be plotted versus the separate distance of the test particle pair on the D3-brane numerically. Here Figure 1 is plotted for a fixed value of b (fixed temperature) and Q (related to chemical potential) with different values of α. To compare with the case in [9], we take b=0.5 and 2L2/r0=r0/(πα′)=1 here. In Figure 1, Figure 1(a) is plotted for a small value of chemical potential (Q=0.2) while Figure 1(b) is for a larger value of chemical potential (Q=1.4). In all of the plots from top to bottom α=0.1,0.25,0.6,1.0,1.3. From the figures, we can indeed see that there exist two critical values of the electric field: one is related to α=1 (E=Ec) and the other is at α=0.25 (E=Es=0.25Ec).
The total potential versus distance x with two different values of Q. (a) Q=0.2; (b) Q=1.4. In all of the plots from top to bottom α=0.1,0.25,0.6,1.0,1.3.
In order to see the effect of chemical potential clearly, we plot the potential versus x with fixed α and varied Q in Figure 2. From Figure 2(a), we can see that as Q increases the height and width of the potential barrier both increase. Meanwhile, from Figure 2(b), we can see that as Q increases the height of the potential that becomes flat also increases. As we know, higher potential barrier makes the produced pair harder to escape to infinity. So the presence of chemical potential tends to suppress the Schwinger effect. In addition, as shown in Figure 2(b), one of the critical values of the electric field (E=Es=0.25Ec) is not affected by the chemical potential. This can be also understood by looking at the value of Es defined as Es=TFrt2/L2.
The total potential versus distance x with fixed α and varied Q. (a) α=0.6; (b) α=0.25. In all of the plots from top to bottom Q=0.2,0.8,1.4.
4. Production Rate
In this section, we study the pair production rate. Here we consider an AdS soliton background [10](30)ds2=L2z2-dx02+dx12+dx22+fzdx32+dz2fz+L2dΩ52,with(31)fz=1-1+Q2zzt4+Q2zzt6,where x3-direction is compactified on a circle S1 with radius R=πzt. The AdS boundary is at z=0; the geometry is cut off at z=zt.
The holographic pair production rate is [7](32)Γ~e-SNG+SB2.
To evaluate the pair production rate, one needs to compute the action or the expectation value of a circular Wilson loop on the probe brane. In [10], the circular Wilson loop is chosen to lie in τ-σ plane. As a matter of convenience, here we use the polar coordinate, (r,θ), as follows from [16], so the string worldsheet can be parameterized by z=z(r) in this case. With this ansatz, the induced metric is given by(33)ds2=L2z21+z′2fzdr2+r2dθ2,with z′=dz/dr.
Then the string action can be expressed as(34)SNG=2πL2TF∫0xdrrz21+z′2fz,SB2=-2πTFB01∫0xdrr=-πEx2,where the external electric field is defined as E≡TFB01 with B01 the nonvanishing component of B2 and x stands for the radius of the circular Wilson loop. By minimizing the action, one obtains the equation of motion(35)z′′1+r+2rz′2z-rz′22fzdfzdz+2rfzz=0.
The boundary conditions of (35) are [14] (36)z′z=zc=0,zr=x=z0,z′r=x=-fz1α2-1z=z0,where α is defined in (28).
To proceed further, we need to turn to numerical methods. To compare with the case in [10], we take 2πL2TF=10 and set the endpoint of the soliton as zt=1. Then the whole action is only dependent on α, z0, and Q. In Figure 3, we plot the classical action S and the exponential factor e-S against α with fixed Q=0.2. Other cases with different Q have similar picture. As shown in these figures, the action diverges around a certain value which leads to a vanishing e-S. We know from the above section that when α<αs, with αs≡Es/Ec=z02/zt2, the Schwinger effect does not occur. Thus, this agreement supports that the numerical results of the production rate are consistent with the potential analysis.
S and e-S versus α with fixed Q=0.2. In all plots from left to right z0/zt=0.1,0.5,0.8.
To see the effect of the chemical potential on Schwinger effect, we plot e-S versus α at fixed z0/zt with two different values of Q in Figure 4. From the plots, we can see that e-S decreases as Q increases. This means that the chemical potential suppresses the pair production rate and also agrees with the previous potential analysis. Moreover, as z0/zt increases, the effect of the chemical potential becomes weaker; this phenomenon can be found in Figure 4(b), where the two curves with different Q are nearly overlapped.
e-S versus α with fixed z0/zt. (a) z0/zt=0.1. (b) z0/zt=0.8. In all plots from top to bottom Q=0.2,0.8.
5. Conclusion and Discussion
Schwinger effect in confining gauge theories may be an important ingredient in looking for new aspects of QCD in the presence of strong external fields. In this paper, we have studied the effect of chemical potential on the holographic Schwinger effect by considering a confining D3-brane background with charge. The potential of a test particle pair was obtained by calculating the Nambu-Goto action of string attaching the rectangular Wilson loop at the probe D3-brane. The production rate for various cases was evaluated numerically. The effect of the chemical potential on the production rate was qualitatively shown. From the results, we can indeed see that there exist two critical values of the electric field. In addition, both the potential analysis and the numerical results of the production rate suggest that the presence of chemical potential tend to suppress the Schwinger effect. Interestingly, the instanton effects on the Schwinger effect have been studied in [30]. It is found that the presence of instantons also suppresses the pair production effect at finite temperature.
Competing Interests
The authors declare that they have no competing interests.
Acknowledgments
This research is partly supported by the Ministry of Science and Technology of China (MSTC) under the 973 Project no. 2015CB856904(4). Zi-qiang Zhang is supported by the NSFC under Grant no. 11547204. Gang Chen is supported by the NSFC under Grant no. 11475149. De-fu Hou is partly supported by NSFC under Grants nos. 11375070 and 11221504.
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