Mots-clés : phase transition
@article{TMF_2022_210_3_a5,
author = {I. Ya. Aref'eva and K. A. Rannu and P. S. Slepov},
title = {Anisotropic solution of the~holographic model of light quarks with an external magnetic field},
journal = {Teoreti\v{c}eska\^a i matemati\v{c}eska\^a fizika},
pages = {416--421},
year = {2022},
volume = {210},
number = {3},
language = {ru},
url = {http://geodesic.mathdoc.fr/item/TMF_2022_210_3_a5/}
}
TY - JOUR AU - I. Ya. Aref'eva AU - K. A. Rannu AU - P. S. Slepov TI - Anisotropic solution of the holographic model of light quarks with an external magnetic field JO - Teoretičeskaâ i matematičeskaâ fizika PY - 2022 SP - 416 EP - 421 VL - 210 IS - 3 UR - http://geodesic.mathdoc.fr/item/TMF_2022_210_3_a5/ LA - ru ID - TMF_2022_210_3_a5 ER -
%0 Journal Article %A I. Ya. Aref'eva %A K. A. Rannu %A P. S. Slepov %T Anisotropic solution of the holographic model of light quarks with an external magnetic field %J Teoretičeskaâ i matematičeskaâ fizika %D 2022 %P 416-421 %V 210 %N 3 %U http://geodesic.mathdoc.fr/item/TMF_2022_210_3_a5/ %G ru %F TMF_2022_210_3_a5
I. Ya. Aref'eva; K. A. Rannu; P. S. Slepov. Anisotropic solution of the holographic model of light quarks with an external magnetic field. Teoretičeskaâ i matematičeskaâ fizika, Tome 210 (2022) no. 3, pp. 416-421. http://geodesic.mathdoc.fr/item/TMF_2022_210_3_a5/
[1] I. Y. Aref'eva, K. Rannu, P. Slepov, “Holographic model for heavy quarks in anisotropic hot dense QGP with external magnetic field”, JHEP, 07 (2021), 161, 31 pp., arXiv: 2011.07023 | DOI | MR
[2] I. Ya. Arefeva, “Golograficheskoe opisanie kvark-glyuonnoi plazmy, obrazuyuscheisya pri stolknoveniyakh tyazhelykh ionov”, UFN, 184:6 (2014), 569–598 | DOI
[3] I. Ya. Aref'eva, “Theoretical studies of the formation and properties of quarkGluon matter under conditions of high baryon densities attainable at the NICA experimental complex”, Phys. Part. Nucl., 52:4 (2021), 512–521 | DOI
[4] I. Ya. Aref'eva, A. A. Golubtsova, E. Gourgoulhon, “Analytic black branes in Lifshitz-like backgrounds and thermalization”, JHEP, 09 (2016), 142, 36 pp., arXiv: 1601.06046 | DOI | MR
[5] I. Ya. Aref'eva, K. Rannu, “Holographic anisotropic background with confinement-deconfinement phase transition”, JHEP, 05 (2018), 206, 58 pp., arXiv: 1802.05652 | DOI | MR
[6] I. Ya. Aref'eva, A. A. Golubtsova, “Shock waves in Lifshitz-like spacetimes”, JHEP, 04 (2015), 011, 33 pp. | DOI | MR
[7] I. Ya. Aref'eva, K. Rannu, P. Slepov, “Holographic anisotropic model for light quarks with confinement-deconfinement phase transition”, JHEP, 06 (2021), 090, 27 pp., arXiv: 2009.05562 | DOI | MR
[8] I. Ya. Arefeva, K. A. Rannu, P. S. Slepov, “Anizotropnye resheniya v golograficheskoi modeli dlya tyazhelykh kvarkov s vneshnim magnitnym polem”, TMF, 207:1 (2021), 44–57 | DOI | DOI | MR
[9] I. Ya. Arefeva, K. A. Rannu, P. S. Slepov, “Prostranstvennopodobnye petli Vilsona v polnostyu anizotropnoi modeli”, TMF, 206:3 (2021), 400–409 | DOI | DOI | MR
[10] P. S. Slepov, “A way to improve the string tension dependence on temperature in holographic model”, Phys. Part. Nucl., 52:4 (2021), 560–563 | DOI
[11] K. A. Rannu, “Holographic model for light quarks in anisotropic background”, Phys. Part. Nucl., 52:4 (2021), 555–559 | DOI
[12] M. W. Li, Y. Yang, P. H. Yuan, “Approaching confinement structure for light quarks in a holographic soft wall QCD model”, Phys. Rev. D, 96:6 (2017), 066013, 17 pp., arXiv: 1703.09184 | DOI | MR