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Effect of Strong Magnetic Field on Competing Order Parameters in Two-Flavor Dense Quark Matter.

1. Introduction

The existence of deconfined quark matter in the dense interior of a neutron star is an interesting question that has spurred research in several new directions in nuclear astrophysics. On the theoretical side, it has been realized that cold and dense quark matter must be in a superconductor/superfluid state [1-6] with many possible intervening phases [7-14] between a few times nuclear matter density and asymptotically high density, where quarks and gluons interact weakly. The observational impact of these phases on neutron star properties can be varied and dramatic [15-22]. Therefore, it is of interest to situate theoretical ideas and advances in our understanding of dense quark matter in the context of neutron stars, which serve as unique astrophysical laboratories for such efforts. The phase structures of hot quark matter have been probed in experiments such as in heavy ion collisions at the Relativistic Heavy Ion Collider (RHIC) and at the Large Hadron Collider (LHC). It is estimated in [23-25] that the magnetic field originating from off-central nucleon-nucleon collisions at these colliders can be as large as [10.sup.18]-[10.sup.20] G. On the astrophysical side, the strength of the magnetic field in some magnetars is of the order 1014-1015 G [26], while in the core of such objects, magnetic field might reach up to [10.sup.18]-[10.sup.19]G. Therefore, it is not surprising that many recent works have stressed the role of strong magnetic fields on hot or dense quark matter [27-35].

At very high density (i.e., [mu] [much greater than][[LAMBDA].sub.QCD], where [mu] is the baryon chemical potential and [[LAMBDA].sub.QCD] is the scale of quantum chromodynamics) and for number of flavors [N.sub.f] = 3, the preferred pairing pattern is a flavor and color democratic one termed as the color-flavor-locked (CFL) phase [7]. This idealized phase, while displaying the essentially novel features of the color superconducting state, is unlikely to apply to the bulk of the neutron star matter, since even ten times nuclear matter saturation density ([[rho].sub.0]) only corresponds to a quark chemical potential [mu] ~ 500 MeV. At these densities, quark mass and strong coupling effects can be important and must be treated nonperturbatively. It is reasonable to think that the strange quark current mass, being much larger than that of the up and down quarks, inhibits pairing of strange quarks with light quarks. For the purpose of this work, we therefore adopt the scenario of quark matter in the two-flavor superconducting phase, which breaks the color SU(3) symmetry to SU(2), leaving light quarks of one color (say "3") and all colors of the strange quark unpaired. Although this phase initially appeared to be disfavored in compact stars [36, 37] once constraints of neutrality were imposed within a perturbative approach to quark masses, the NJL model where masses are treated dynamically still allows for the 2SC phase. Since the issue is not settled, we proceed by adopting the NJL model which best highlights the competition between the chiral and diquark condensates in a straightforward way. Also, our results will be qualitatively true for the 2SC+s phase [9,10], which can be studied similarly by simply embedding the strange quark, which is inert with respect to pairing, in the enlarged three-flavor space. The additional complications of compact star constraints have been examined before [27, 35, 38] and do not change the main qualitative conclusions of the present work, namely, that strong magnetic field alters the competition between the chiral and diquark order parameters from the weak-field case.

Our objective in this paper is a numerical study of the competition between the chiral and diquark condensates at moderately large [mu] and large magnetic field using the NJL model, similar in some respects to previous works [8, 9, 39-41], which treat the quark mass nonperturbatively. Instanton-based calculations and random-matrix methods have also been employed in studying the interplay of condensates [42-44]. In essence, smearing of the Fermi surface by diquark pairing can affect the onset of chiral symmetry restoration, which happens at [mu] ~ [M.sub.q], where Mq is the constituent quark mass scale [45]. Since Mq appears also in the (Nambu-Gorkov) quark propagators in the gap equations, a coupled analysis of chiral and diquark condensates is required. This was done for the two-flavor case with a common chemical potential in [8], but for zero magnetic field. We use a self-consistent approach to calculate the condensates from the coupled gap equations and find small quantitative (but not qualitative) differences from the results of Huang et al. [8] for zero magnetic field. This small difference is most likely attributed to a difference in numerical procedures in solving the gap equations. We also address the physics of chiral and diquark condensates affected by large in-medium magnetic field that are generated by circulating currents in the core of a neutron or hybrid star. Magnetic field in the interior of neutron stars may be as large as [10.sup.19] G, pushing the limits of structural stability of the star [46, 47]. There is no Meissner effect for the rotated photon, which has only a small gluonic component; therefore, magnetic flux is hardly screened [48], implying that studies of magnetic effects in color superconductivity are highly relevant. Note that the rotated gluonic field, which has a very small photonic component, is essentially screened due to the 2SC phase. Including the magnetic interaction of the quarks with the external field leads to qualitatively different features in the competition between the two condensates, and this is the main result of our work.

In Section 2, we state the NJL model Lagrangian for the 2SC quark matter. In Section 3, we recast the partition function and thermodynamic potential in terms of interpolating bosonic variables. In Section 4, we obtain the gap equations for the chiral and diquark order parameters by minimizing the thermodynamic potential (we work at zero temperature throughout since typical temperature in stars [] [much less than] [mu]). In Section 5, we discuss our numerical results for the coupled evolution of the condensates as functions of a single ratio of couplings, chemical potential, and magnetic field before concluding in Section 6.

2. Lagrangian for 2SC Quark Matter

The Lagrangian density for two quark flavors (Nj = 2) applicable to the scalar and pseudoscalar mesons and scalar diquarks is

[mathematical expression not reproducible], (1)

where q = [q.sub.ia] is a Dirac spinor which is a doublet (where i = {u, d}) in flavor space and triplet (where a = {1,2,3})in color space. The charge-conjugated fields are defined as [[bar.q].sup.C] = [-q.sup.T] C and [q.sup.C] = C[[bar.q].sup.T] with charge-conjugation matrix C = - i[[gamma].sup.0][[gamma].sup.2]. The components of [??] = ([[tau].sup.1], [[tau].sup.2], [[tau].sup.3]) are the Pauli matrices in flavor space and [([[epsilon].sub.f]).sub.ij] and [([[epsilon].sub.c]).sup.a[beta]3] are the antisymmetric matrices in flavor and color spaces, respectively. The common quark chemical potential is denoted as [??] (for simplicity we assume a common chemical potential for all quarks; in an actual neutron star containing some fraction of charge neutral 2SC or 2SC+s quark matter in [beta]-equilibrium, additional chemical potentials for electric charge and color charges must be introduced in the NJL model; furthermore, there can be more than one diquark condensate and in general [M.sub.u] [not equal to] [M.sub.d] [not equal to] [M.sub.s][9]) and [??] = diag([m.sub.u], [m.sub.d]) is the current quark mass matrix in the flavor basis. We take the exact isospin symmetry limit, [m.sub.u] = [m.sub.d] = [m.sub.0] [not equal to] 0. The U(1) and SU(3)C gauge fields are denoted by [A.sub.[mu]] and [G.sub.[mu]], respectively. Here, e is the electromagnetic charge of an electron and g is the SU[(3).sub.c] coupling constant. The electromagnetic charge matrix for quark is defined as Q = [Q.sub.f] [cross product] [1.sub.c] with [Q.sub.f] = diag(2/3, -1/3) (in unit of e). The couplings of the scalar and diquark channels are denoted as [G.sub.S] and [G.sub.D], respectively. In general, one can extend the NJL Lagrangian considered in (1) by including vector and't Hooft interaction terms which can significantly affect the equation of state of the compact stars with superconducting quark core [49, 50]. In this paper, our main aim is to investigate the competition between chiral and diquark condensates and therefore we do not consider other interactions in our analysis.

We introduce auxiliary bosonic fields to bosonize the four-fermion interactions in Lagrangian (1) via a Hubbard-Stratonovich (HS) transformation. The bosonic fields are

[mathematical expression not reproducible], (2)

and after the HS transformation, the bosonized Lagrangian density becomes

[mathematical expression not reproducible], (3)

where m = [m.sub.0] + a. We set [??] = 0 in our analysis, which excludes the possibility of pion condensation for simplicity [51]. Order parameters for chiral symmetry breaking and color superconductivity in the 2SC phase are represented by nonvanishing vacuum expectation values (VEVs) for a and [DELTA]. The diquark condensates of u and d quarks carry a net electromagnetic charge, implying that there is a Meissner effect for ordinary magnetism, while a linear combination of the photon and gluon leads to a "rotated" massless U(1) field which is identified as the in-medium photon. We can write the Lagrangian in terms of rotated quantities using the following identity:

[mathematical expression not reproducible]. (4)

In the r.h.s. of (4) all quantities are rotated. In flavor [cross product] color space in units of the rotated charge of an electron e = [square root of [square root of (3ge)/ [square root of (3[g.sup.2] + [e.sup.2])] the rotated charge matrix is

[??] = [Q.sub.f] [cross product] [1.sub.c] - [1.sub.f] [cross product] [T.sup.8.sub.c]/2[square root of 3]. (5)

The other diagonal generator [T.sup.3.sub.c] plays no role here because the degeneracy of colors 1 and 2 ensures that there is no long range 3-field gluon. We take a constant rotated background U(1) magnetic field B = B[??] along +z axis. The gapped 2SC phase is [??]-neutral, requiring a neutralizing background of strange quarks and/or electrons. The strange quark mass is assumed to be large enough at the moderate densities under consideration so that strange quarks do not play any dynamical role in the analysis.

3. Thermodynamic Potential

The partition function in the presence of an external magnetic field B in the mean field approximation is given by

[mathematical expression not reproducible], (6)

where N is the normalization factor, [beta] = [T.sup.-1] is the inverse of the temperature T, B is the external magnetic field, and [??] is the Lagrangian density in terms of the rotated quantities. The full partition function [??] can be written as a product of three parts, [mathematical expression not reproducible]. Here, [[??].sub.c] serves as a constant multiplicative factor, [[??].sub.1,2] denotes the contribution for quarks with colors "1" and "2," and [[??].sub.3] is for quarks with color "3." These three parts can be expressed as

[mathematical expression not reproducible]. (7)

The kinetic operators [L.sub.kin](q, [q.sup.c]) now read (i[??] + [mu][[gamma].sup.0] - M), where M = [m.sub.0] + [sigma], and we use the notation [[DELTA].sup.- ](/[[DELTA].sup.+]) = - i[[gamma].sub.5][[epsilon].sub.f][[epsilon][delta].sub.c][DELTA](/[[DELTA].sup.* ]). In flavor [cross product] color space in units of [??] = [square root of (3[g.sub.2]/ [square root of (3[g.sup.2] + [e.sup.2])] the rotated charge matrix is given by [??] = Q [cross product] [1.sub.c] - [1.sub.f] [cross product] [T.sup.8]/2[square root of 3]. Here, [1.sub.c] and [1.sub.f] are unit matrix on color and flavor spaces, respectively. In our case, this translates to [??] charges [u.sub.1,2] = 1/2, [d.sub.1,2] = -1/2, [u.sub.3] = 1 and [d.sub.3] = 0. With s-quarks as inert background, we also have [s.sub.1,2] = -1/2 and [s.sub.3] = 0. Imposing the charge neutrality and [beta]-equilibrium conditions is known to stress the pairing and lead to gluon condensation and a strong gluo-magnetic field [52]. The role of such effects has been studied in [27], but here our focus is on the interdependence of the condensates and their response to the strong magnetic field.

Evaluation of the partition function and the thermodynamic potential, [OMEGA] = -T ln L/V (where V is the volume of the system), is facilitated by introducing eight-component Nambu-Gorkov spinors for each color and flavor of quark, leading to

ln [Z.sub.1,2] = 1/2 ln {Det ([beta][G.sup.-1])}, ln [Z.sub.3] = 1/2 ln {Det ([beta][G.sup.-1.sub.0])}, (8)

where G and [G.sub.0] are the quark propagators and inverse of the propagators is given by

[mathematical expression not reproducible], (9)

with [mathematical expression not reproducible]. The determinant computation is simplified by reexpressing the Q-charges in terms of charge projectors in the color-flavor basis, following techniques applied for the CFL phase [53]. The color-flavor structure of the condensates can be unraveled for the determinant computation by introducing energy projectors [8] and moving to momentum space, whereby we find

[mathematical expression not reproducible], (10)

where [E.sup.[+ or -].sub.[DELTA],a] = [square root of (([E.sup.[+ or - ].sub.p,a])2 + [[DELTA].sup.2])] with [E.sup.[+ or -].sub.p,a] = [E.sup.[+ or - ].sub.p,a] [+ or -] [mu] and a = {0,1, [+ or -] 1/2}. The energy [E.sub.p,a] is defined as [E.sub.p,a] = [square root of ([p.sup.2.sub.[perpendicular to]a] + [P.sup.2.sub.z] + [m.sup.2])]; if a = 0 then [p.sup.2.sub.[perpendicular to]a] = [p.sup.2.sub.x] + [p.sup.2.sub.y]; else [p.sup.2.sub.[perpendicular to]a] = 2[absolute value of (a)][??]Bn. The sum over [p.sub.0] = i[[omega].sub.k] denotes the discrete sum over the Matsubara frequencies; n labels the Landau levels in the magnetic field which is taken in the [??] direction.

4. Gap Equations and Solution

Using the following identity we can perform the discrete summation over the Matsubara frequencies

[summation over ([p.sub.0])] ln [[[beta].sup.2] - [E.sup.2])] = [beta][E + 2Tln (1 + [e.sup.-[beta]E])] = [beta]f(E). (11)

Then we go over to the 3-momentum continuum using the replacement [[summation].sub.p] [right arrow] V[(2[pi]).sup.-3] [integral] [d.sup.3]p, where V is the thermal volume of the system. Finally, the zero-field thermodynamic potential can be expressed as

[mathematical expression not reproducible]. (12)

In presence of a quantizing magnetic field, discrete Landau levels suggest the following replacement:

[mathematical expression not reproducible], (13)

where [[alpha].sub.n] = 2 - [[delta].sub.n0] is the degeneracy factor of the nth Landau level (all levels are doubly degenerate except the zeroth level).

The thermodynamic potential in presence of magnetic field is given by

[mathematical expression not reproducible]. (14)

In either case, we can now solve the gap equations obtained by minimizing the (zero-temperature) thermodynamic potential [OMEGA] obtained in presence of magnetic field.

Chiral gap equation: [partial derivative][OMEGA]/[partial derivative]m = 0, Diquark gap equation: [partial derivative][OMEGA]/[partial derivative][DELTA] = 0. (15)

Since the above equations involve integrals that diverge in the ultraviolet region, we must regularize the divergences in order to obtain physically meaningful results. We choose to regulate these functions using a sharp cutoff (step function in [absolute value of (p)]), which is common in effective theories such as the NJL model [39,40], although one may also employ a smooth regulator [7, 53] without changing the results qualitatively for fields that are not too large (e.g., a smooth cutoff was employed in [53] to demonstrate the de Haas-van Alphen oscillations in the gap parameter at very large magnetic field). The momentum cutoff restrict the number of completely occupied Landau levels [n.sub.max] which can be determined as follows:

[mathematical expression not reproducible]. (16)

We use the fact that [p.sup.2.sub.z] [greater than or equal to] 0 to compute [n.sub.max]. For magnetic field B [??] 0.02 Ge[V.sup.2] (~[10.sup.17] G, conversion to Gauss is given by 1 Ge[V.sup.2] = 5.13 x [10.sup.19] G), [n.sub.max] is of the order of 50, and the discrete summation over Landau levels becomes almost continuous. In that case, we recover the results of the zero magnetic field case as described in the next section. For fixed values of the free parameters, we were able to solve the chiral and diquark gap equations self-consistently, for B = 0 as well as large B. Before discussing our numerical results, we note the origin of the interdependence of the condensates. The chiral gap equation contains only GS which is determined by vacuum physics but also depends indirectly on [G.sub.D]/[G.sub.S] (a free parameter) through A, which is itself dependent on the constituent m = [m.sub.0] + [sigma]. Our numerical results can be understood as a consequence of this coupling and the fact that a large magnetic field stresses the [bar.q]q pair (same [??] charge and opposite spins implied antialigned magnetic moments) while strengthening the qq pair (opposite [??] charge and opposite spins implied aligned magnetic moments).

5. Numerical Analysis

In order to investigate the competition between the chiral and the diquark condensates, in this section, we solve the two coupled gap equations (15) numerically. These gap equations involve integrals that have diverging behavior in the high-energy region (this is an artifact of the nonrenormalizable nature of the NJL model). Therefore, to obtain physically meaningful behavior, one has to regularize the diverging integrals by introducing some cutoff scale A. A sharp cutoff function sometimes leads to unphysical oscillations in thermodynamical quantities of interest and especially for a system with discrete Landau levels. A novel regularization procedure called "Magnetic Field Independent Regularization" (MFIR) scheme [54, 55] can remove the unphysical oscillations completely even if a sharp cutoff function is used within MFIR. To reduce the unphysical behavior, it is very common in literature to use various smooth cutoff functions although they cannot completely remove the spurious oscillations. Here, we list a few of them:

(i) Fermi-Dirac type [56]: [f.sub.c]([p.sub.a]) = (1/2)[1- tanh(([p.sub.a] - [LAMBDA])/[epsilon])], where [alpha] is a smoothness parameter.

(ii) Woods-Saxon type [38]: [f.sub.c]([p.sub.a]) = [[1 + exp(([p.sub.a] - [lambda])/ [alpha])].sup.-1], where a is a smoothness parameter.

(iii) Lorentzian type [57]: [f.sub.c]([p.sub.a]) = [[1 + ([p.sup.2.sub.a]/ [[kappa].sup.2])N].sup.-1], where N is a positive integer,

where [p.sub.a] = [square root of ([p.sup.2.sub.[perpendicular to],a] + [P.sup.2.sub.z], with [p.sup.2.sub.[perpendicular to],0] = [P.sup.2.sub.x] + [P.sup.2.sub.y] for a = 0 and [p.sup.2.sub.[perpendicular to],a] = 2[absolute value of (a)][bar.e]Bn for a = 1, [+ or -] 1/2. Cutoff functions become smoother for larger values of a or N in case of the Lorentzian type of regulator. We have checked our numerical results for different cutoff schemes like sharp cutoff (Heaviside step function) and various smooth cutoff parameterizations as mentioned above and found that our main results are almost insensitive for different cutoff schemes. We therefore use a smooth Fermi-Dirac type of regulator with [alpha] = 0.01A throughout numerical analysis.

One can fix various NJL model parameters, the bare quark mass [m.sub.0], the momentum cutoff A, and the scalar coupling constant Gs by fitting the pion properties in vacuum, namely, the pion mass [m.sub.[pi]] = 134.98 MeV, the pion decay constant [f.sub.[pi]] = 92.30 MeV, and the constituent quark mass m ([mu] = 0) = 0.33 GeV. Similarly, one can fix the diquark coupling constant GD by fitting the scalar diquark mass (~ 600 MeV) to obtain vacuum baryon mass of the order of ~900 MeV [58]. There are some factors that can, in principle, alter those model parameters, for example, strength of the external magnetic field, temperature, and choice of the cutoff functions. Assuming that those factors have only small effects on the parameters and expecting that our numerical results would not change qualitatively, we fix the parameters in the isospin symmetric limit as follows (a discussion of the parameter choice can be found in [59]):

[m.sub.u,d] = [m.sub.0] = 5.5 MeV, [LAMBDA] = 0.6533 GeV, [G.sub.S] = 5.0163 Ge[V.sup.-2], [G.sub.D] = [rho][G.sub.S], (17)

where [rho] is a free parameter. Although Fierz transforming one gluon exchange implies [rho] = 0.75 for [N.sub.c] = 3 and fitting the vacuum baryon mass gives [rho] = 2.26/3 [58], the underlying interaction at moderate density is bound to be more complicated; therefore we choose to vary the coupling strength of the diquark channel [G.sub.D] to investigate the competition between the condensates.

We investigate the behavior of the chiral and diquark gaps along the chemical potential direction in presence of magnetic field for different magnitudes of the coupling ratio [epsilon] (= [G.sub.D]/[G.sub.S]) at zero temperature. Before we discuss the influence of diquark gap on the chiral phase transition, we first demonstrate the behavior of the chiral gap for [DELTA] = 0 case (equivalently p = 0) for different magnitudes of eB. The choice of [??]B is made to see the effects of the inclusion of different Landau levels in the system. In Table 1, we show the values of [n.sup.max.sub.1] and [n.sup.max.sub.2] and the corresponding values of the transition magnetic field [??][B.sub.t]. For example, if [??]B < [??][B.sub.t], then the number of fully occupied Landau levels n > [n.sup.max]. In Figure 1, we show m as functions of [mu] in absence of diquark gap for different choices of [??]B. In Figures 1(a) and 1(b), we show m in absence of magnetic field ([??]B = 0) and in the weak magnetic field limit ([??]B = 0.005 Ge[V.sup.2] or equivalently ~2.5 x 1017G), respectively. One can see that these two figures look almost identical. The reason is that the number of completely occupied Landau levels, [n.sub.max], becomes very large (e.g., [n.sup.max.sub.1] ~ 40 for [??]B ~ 0.005 Ge[V.sup.2]) in the weak magnetic field limit, making the discrete Landau level summation quasicontinuous. As we increase the magnetic field, noticeable deviations appear in the behavior of the chiral gap as seen in Figures 1(c) to 1(f).

From Figure 1, it is clear that we get multiple solutions to the chiral gap equation for a small range of [mu] around the chiral phase transition region. For example, we get three solutions to the chiral gap equation for a narrow window of [mu] for zero or weak magnetic field ([??] 2.5 x [10.sup.17] G) cases. These three solutions correspond to the stable, metastable, and unstable branches of the system. In Figure 2(a), we plot the values of [OMEGA] corresponding to the three solutions obtained in the small [mu]-window. The value of the gap m for which [OMEGA] is the lowest corresponds to the stable solution at any given density. The critical chemical potential [[mu].sub.c] (where the chiral and the diquark phase transitions occur) is the point where the first derivative of [omega] (and the gaps) behave discontinuously. The location of [[mu].sub.c] gives the transition point from the stable region to the metastable region of the system. This can easily be identified by looking at the behavior of [OMEGA] as shown in Figure 2(a). We follow this method to locate the first-order phase transition point. In Figure 2(b), we plot [[mu].sub.c] as a function of [??]B. We observe that [[mu].sub.c] oscillates with [??]B with dips whenever [[LAMBDA].sup.2]/(2[absolute value of (a)][??]B) takes an integer value, following the Shubnikov de Haas-van Alphen effect. Similar oscillations in the density of states and various thermodynamic quantities are observed in metals in presence of magnetic field at very low temperature. The magnitude of oscillations becomes more pronounced as we increase the magnetic field. If [??]B [??] 0.21 Ge[V.sup.2] (~[10.sup.9] G), only the zeroth Landau level is completely occupied as evident from Table 1.

We observe multiple intermediate transitions (from Figures 1(c) to 1(d)) due to the filling of successive Landau levels, and for a particular [mu], sometimes there are two stable solutions at different densities for the same pressure. Similar multiple solutions of the gaps have been observed in the context of magnetized-NJL model with repulsive vector interactions [30]. Comparing the values of m at [mu] = 0 for very strong magnetic field, one finds that m increases with [??]B. This is the magnetic catalysis effect [60-63]. It is also interesting to note that with increasing magnetic fields the spread of the metastable region (the [mu]-window where we have multiple solutions) becomes wider. For example, the spread of the metastable regions for [??]B = 0.5 Ge[V.sup.2] is about 0.22 GeV and for [??]B = 0.25 Ge[V.sup.2] is about 0.12 GeV. These findings suggest the possibility of multiple phases with different values of dynamical mass in the presence of inhomogeneous magnetic fields, which we postpone to a future investigation. It is important to mention that the multiple solutions observed in chiral condensate as function of chemical potential would disappear when plotted as function of baryon density defined as <bar.q][[gamma].sup.0] q> (see, e.g., Section 4.2 in [64]).

In Figure 3, we show m and [DELTA] as functions of [mu] for different [rho] in presence of strong magnetic field. In [8], the competition of chiral and diquark gaps without any magnetic field was discussed in great detail. We observe that m increases with the increase of [??]B. For example, m ~ 0.35 GeV for [??]B = 0.15 Ge[V.sup.2] and m - 0.48 GeV for [??]B = 0.5 Ge[V.sub.2]. In [8], it was shown that with the increase of [rho] the first-order transition of the chiral and diquark gaps becomes crossover through a second-order phase transition. When a strong magnetic field is present, we find that the crossover becomes a first-order transition. This is an important finding of this work, which has several implications for neutron star physics as discussed in the conclusion. The critical chemical potential [[mu].sub.c] is almost same for both the chiral and diquark phase transition but takes on smaller values as we increase [rho] for a fixed [??]B (as shown in Figure 3).

In the weak (or zero) magnetic field limit, A appears at a smaller [mu] with increasing [rho] and rises smoothly from zero, until it becomes discontinuous at [[mu].sub.c]. At [[mu].sub.c] the chiral gap m also changes discontinuously, with the jumps in the gaps decreasing with increasing [rho]. For instance, in Table 2 we see the jump in the chiral gap ([[delta].sub.m]) decreases from 0.250 GeV to 0.133 GeV as we increase [rho] from 0.75 to 1.05. The corresponding jump in diquark gap ([S.sub.[DELTA]]) decreases from 0.077 GeV to 0.066 GeV. This picture does not change qualitatively until we go above a critical value [rho] = [[rho].sub.c] ~ 1.09. As long as [rho] < [[rho].sub.c], the jumps in the gaps [[DELTA].sub.m] and [[delta].sub.[DELTA]] remain nonzero but decrease as [rho] moves towards [[rho].sub.c]. In other words, the metastable region in [OMEGA] as shown in Figure 2(a) shrinks with increasing [rho]. At [rho] = [[rho].sub.c] the metastable and unstable regions vanish completely. This qualifies it to be a second-order phase transition. Above [rho] > [[rho].sub.c], the gaps m and A are smoothly varying resulting in a smooth crossover. However, there always exists a pseudo-transition point ([[mu].sup.p.sub.c]) around which fluctuations/variations of the condensates (i.e., derivatives of m and [DELTA] with respect to [mu]) are sharply peaked. The width of these peaked distributions broadens with further increase of [rho], and [DELTA] moves to the left with increasing [rho]. These results for [??]B ~ 0 agree qualitatively with the zero-field results of [8] with minor quantitative differences at less than a few percent level. The region where the condensates coexist was termed by them as the "mixed broken phase," since both chiral and (global) color symmetries are broken here. While it should not be confused with a genuine mixed phase, since the free energy admits a unique solution to the gap equations in this regime, it is clear that the width of this overlap region increases with increasing [rho].

The competition between the condensates is driven by the strong magnetic field, which in the case of m is a stress, since the chiral condensate involves quark spinors of opposite spin and same [??]-charge. On the other hand, the diquark condensate, with opposite spin and Q-charge, is strengthened by the strong magnetic field. Thus, we expect a strengthening of the competition between the two condensates, resulting in a qualitative change from the zero-field case. With increasing [rho], similar to the [??]B = 0 case, [[delta].sub.m] and [[delta].sub.[DELTA]] decrease and the transition is first order in nature. The dramatic effect we observe is that the mixed broken phase for large [rho] at [??]B = 0 is no longer present in case of strong magnetic field case and the crossover region is replaced by a first-order transition. Specifically, in Table 2, we see, for [rho] = 1.25, a smooth crossover in the [??]B = 0 case at [[mu].sup.p.sub.c] - 0.255 GeV becomes a first-order transition with [[delta].sub.m] = 0.185 GeV and [[sigma].sub.[DELTA]] = 0.122 GeV at [[mu].sub.c] - 0.284 GeV for [??]B = 0.1 Ge[V.sup.2]. The simultaneous appearance of the discontinuity in the gaps for large magnetic field case, at almost the same [mu] = [[mu].sub.c] where both the condensates have their most rapid variation in the [??]B = 0 case, is a physical feature and is also cutoff insensitive. We have checked that magnetic field [mathematical expression not reproducible] does not notably alter the competition between the condensates from the zero magnetic field case.

6. Conclusions

We study the effects of a strong homogeneous magnetic field on the chiral and diquark condensates in a two-flavor superconductor using the NJL model. We implement a self-consistent scheme to determine the condensates, by numerically iterating the coupled (integral) equations for the chiral and superconducting gaps. We obtain results for the nature of the competition between these condensates in two cases, at weak magnetic field limit where our results are qualitatively same as zero magnetic field results [8] and at strong magnetic field, where we find the competition between the gaps increases strongly causing a discontinuity in the gaps and disrupting the "mixed broken phase." This is a result of the modified free energy of the quarks in the condensate when subjected to a strong magnetic field. For magnetic fields as large as B ~ [10.sup.19] G, the antialigned magnetic moments of the quarks in the chiral condensate change the smooth crossover of the chiral transition to a sharp first-order transition. The diquark gap also becomes discontinuous at this point. For magnetic fields B [??] 1018 G, there is no significant effect of the magnetic field on the competition between the condensates and zero-field results apply.

These findings can impact the physics of hybrid stars (neutron stars with quark matter) or strange quark stars in several ways. Firstly, the structure of neutron stars is strongly affected by a first-order phase transition, with the possibility of a third family of compact stars in addition to neutron stars and white dwarfs [65] that is separated from conventional neutron stars by a radius gap of a few km. We can speculate that strange stars or hybrid stars with superconducting quark cores inside them belong to this third family. Since we find that a strong magnetic field increases the likelihood of a first-order phase transition and hence a mixed phase, magnetars could also possibly belong to this category of compact stars since they permit quark nucleation [66] and carry large interior magnetic fields which modify their mass-radius relationship [67]. Secondly, it was pointed out in [27] that for large values of the local magnetic field and in the small density window of the metastable region, it is possible to realize domains or nuggets of superconducting regions with different values for the gap. Charge neutrality can also disrupt the mixed broken phase, but the oscillations of the chiral gap remain, leading to nucleation of chirally restored droplets. Such kinds of nucleation and domain formation will release latent heat that might be very large owing to the large value of the magnetic field, serving as an internal engine for possible energetic events on the surface of the neutron star [68, 69]. Such internal mechanisms are unlikely to occur in a pure neutron star without a quark core. Thirdly, strong magnetic fields and quark cores affect the radial and nonradial oscillation modes of neutron stars, which could be a discriminating feature in the gravitational wave signal from vibrating neutron stars. The frequency of the fundamental radial mode shows a kink at the density characterizing the onset of the mixed phase, and the frequencies depend on the magnetic field [70]. Nonradial modes such as g-modes can probe the density discontinuity arising as a result of the phase transition in neutron stars [71] or strange quark stars [72], although the effect of magnetic fields in this context is as yet unexplored. Another important aspect of rotating compact stars is the r-modes [73], which could be responsible for spinning down neutron stars or strange quark stars from their Kepler frequency down to the observed values seen in low-mass X-ray binaries. The effects of a strong magnetic field on the r-mode driven spin-down of neutron stars have been studied in [74,75], while r-modes in crystalline quark matter are discussed in [76]. The even-parity counterpart for the r-modes which include nonradial oscillation modes such as the f- and p-modes have also been explored for the case of strange quark stars in [77, 78]. Our findings give additional motivation to the study of such interesting effects associated with a first-order transition in neutron stars with strong magnetic fields, and a systematic study of these effects in the new era of gravitational waves and neutron star observations may finally reveal the presence of quark matter in the core of neutron stars.

Competing Interests

The authors declare that they have no competing interests.


Tanumoy Mandal is supported by funding from the Carl Trygger Foundation under Contract CTS-14:206 and the Swedish Research Council under Contract 621-2011-5107. Prashanth Jaikumar is supported by the National Science Foundation under Grant no. PHY 1608959.


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Tanumoy Mandal (1) and Prashanth Jaikumar (2)

(1) Department of Physics and Astronomy, Uppsala University, Box 516, 75120 Uppsala, Sweden

(2) Department of Physics and Astronomy, California State University Long Beach, Long Beach, CA 90840, USA

Correspondence should be addressed to Tanumoy Mandal;

Received 29 November 2016; Accepted 9 January 2017; Published 14 February 2017

Academic Editor: Edward Sarkisyan-Grinbaum

Caption: FIGURE 1: Chiral gap m as functions of [mu] for [rho] = [G.sub.D]/[G.sub.S] = 0 with increasing magnetic field [??]B at T = 0.

Caption: FIGURE 2: (a) Thermodynamic potential ([OMEGA]) for [DELTA] = 0 and [??]B = 0 as a function of [mu]. The stable metastable and unstable branches of n are shown beside the curves. (b) The critical chemical potential for chiral phase transition ([[mu].sub.c]) for [delta] = 0 as a function of [??]B.

Caption: FIGURE 3: The gaps m (different blue colors) and [DELTA] (different brown colors) as functions of [mu] for different [rho] in presence of strong magnetic field: (a) [??]B = 0.15 Ge[V.sup.2] and (b) eB = 0.5 Ge[V.sup.2]. The curves with square, circle, triangle, and diamond represent [rho] = 0.75,1,1.25,1.5, respectively. The discontinuities in gaps signify a first-order phase transition.
Table 1: The value of transition magnetic field [??][B.sub.t] at
successive numbers of fully occupied lowest Landau levels
[n.sup.max.sub.a] where a = 1,1/2 are the two possible values of
the rotated charge [??].

[n.sup.max.sub.1]/                 [??][B.sub.t]   [[[LAMBDA].sup.2]/
Int] [[LAMBDA].sup.2]/2[??]B]]     (Ge[V.sup.2])          eB]

1                                      0.213               1
2                                      0.107               2
3                                      0.071               3
4                                      0.053               4
5                                      0.043               5

[n.sup.max.sub.1]/                 [??][B.sub.t]
Int] [[LAMBDA].sup.2]/2[??]B]]     (Ge[V.sup.2])

1                                      0.427
2                                      0.213
3                                      0.142
4                                      0.107
5                                      0.085

TABLE 2: Critical chemical potential, [[mu].sub.c] jumps in the chiral
([[delta].sub.m]) and superconducting ([[delta].sub.m]) order
parameters at for zero and [much greater than]B = 0.1 Ge[V.sup.2] (/5
x [10.sup.18]G) for various values of [rho] = [G.sub.D]/
[G.sub.S]. The nature of the transition is also indicated.

                              [??]B = 0

p      [[delta].sub.m]   [[delta].sub.[DELTA]]   [[mu].sub.c]
            (GeV)                (GeV)              (GeV)

0.75        0.250                0.077              0.332
1.05        0.133                0.063              0.295
1.09          0                    0                0.289
1.15       Smooth               Smooth              0.280
1.25       Smooth               Smooth              0.255

        [??]B = 0             [??]B = 0.1Ge[V.sup.2]

p         Nature      [[delta].sub.m]   [[delta].sub.[DELTA]]
                           (GeV)                (GeV)

0.75   First order         0.227                0.084
1.05   First order         0.214                0.074
1.09   Second order        0.198                0.066
1.15    Crossover          0.185                0.051
1.25    Crossover          0.122                0.038

          [??]B = 0.1Ge[V.sup.2]

p      [[mu].sub.c]     Nature

0.75      0.323       First order
1.05      0.301       First order
1.09      0.297       First order
1.15      0.295       First order
1.25      0.284       First order
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Title Annotation:Research Article
Author:Mandal, Tanumoy; Jaikumar, Prashanth
Publication:Advances in High Energy Physics
Date:Jan 1, 2017
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