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QCD Chiral restoration at finite $T$ under the Magnetic field: Studies based on the instanton vacuum model

We investigate the chiral restoration at finite temperature $(T)$ under the strong external magnetic field $\vec{B}=B_{0}\hat{z}$ of the SU(2) light-flavor QCD matter. We employ the instanton-liquid QCD vacuum configuration accompanied with the linear Schwinger method for inducing the magnetic field. The Harrington-Shepard caloron solution is used to modify the instanton parameters, i.e. the average instanton size $(\barρ)$ and inter-instanton distance $(\bar{R})$, as functions of $T$. In addition, we include the meson-loop corrections (MLC) as the large-$N_{c}$ corrections because they are critical for reproducing the universal chiral restoration pattern. We present the numerical results for the constituent-quark mass as well as chiral condensate which signal the spontaneous breakdown of chiral-symmetry (SB$χ$S), as functions of $T$ and $B$. Besides we find that the changes for the $F_π$ and $m_π$ due to the magnetic field is relatively small, in comparison to those caused by the finite $T$ effect.

preprint2011arXivOpen access
Chung Wen KaoSeung-il Nam
hep-phnucl-th
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Chung Wen KaoSeung-il Nam

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