Abstract
We study the static responses of cold quark matter in the intermediate baryonic density region (characterized by a chemical potential $\mu$) in the presence of a strong magnetic field. We consider in particular, the so-called Magnetic Dual Chiral Density Wave (MDCDW) phase, which is materialized by an inhomogeneous condensate formed by a particle-hole pair. It is shown, that the MDCDW phase is more stable in the weak-coupling regime than the one considered in the magnetic catalysis of chiral symmetry braking phenomenon (MC$\chi$SB) and even than the chiral symmetric phase that was expected to be realized at sufficiently high baryonic chemical potential. The different components of the photon polarization operator of the MDCDW phase in the one-loop approximation are calculated. We found that in the MDCDW phase there is no Debye screening neither Meissner effect in the lowest-Landau-level approximation. The obtained Debye length depends on the amplitude $m$ and modulation $b$ of the inhomogeneous condensate and it is only different from zero if the relation $| \mu -b| > m$ holds. But, we found that in the region of interest this inequality is not satisfied. Thus, no Debye screening takes place under those conditions. On the other hand, since the particle-hole condensate is electrically neutral, the U(1) electromagnetic group is not broken by the ground state and consequently there is no Meissner effect. These results can be of interest for the astrophysics of neutron stars.
Highlights
It is well known that quantum chromodynamics (QCD) has a rich phase structure
We compared the phase characterized by a quark-antiquark chiral condensate with the one with a quark-hole inhomogeneous condensate
We showed that at weak coupling the magnetic dual Chiral Density Wave (MDCDW) phase is the more stable one at any density value
Summary
It is well known that quantum chromodynamics (QCD) has a rich phase structure. In its usual temperature versus baryon-number density phase map, color superconductivity (CS) is the well-established ground state in the asymptotically large density and low-temperature region. Soft transverse modes are the essence of the Landau-Peierls instability because they produce infrared divergencies in the mean square of the fluctuation field that in turn wipe out the average of the condensate at any low temperature Since this does not happen in the MDCDW phase, there exists the possibility that the MDCDW long-range order may remain stable within a range of temperatures feasible for this phase to be stable in the NS core. An interesting question that we want to investigate in this paper is how this competition between the MCχSB phenomenon and the formation of the MDCDW condensate at weak coupling takes place in the dense region to determine the more energetically favored phase Another important feature, which is worthy to study in this context is that, depending on the characteristics of the ground state, quark matter can have different electric screening properties.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
