QCD and holography: confinement and chiral symmetry breaking

Martin Ammon; Johanna Erdmenger

doi:10.1017/CBO9780511846373.014

13 - QCD and holography: confinement and chiral symmetry breaking

from Part III - Applications

Published online by Cambridge University Press: 05 May 2015

Martin Ammon and

Johanna Erdmenger

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Martin Ammon: Affiliation:
Friedrich-Schiller-Universität, Jena, Germany
Johanna Erdmenger: Affiliation:
Max-Planck-Institut für Physik, Munich

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Type: Chapter
Information: Gauge/Gravity Duality
Foundations and Applications
, pp. 399 - 434

DOI: https://doi.org/10.1017/CBO9780511846373.014 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2015

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References

[1] Georgi, H. 1984. Weak Interactions and Modern Particle Theory. Benjamin Cummings.Google Scholar

[2] Maldacena, Juan Martin. 1998. Wilson loops in large N field theories.Phys. Rev. Lett., 80, 4859–862.CrossRef Google Scholar

[3] Sonnenschein, J., and Loewy, A. 2000. On the supergravity evaluation of Wilson loop correlators in confining theories.J. High Energy Phys., 0001, 042.

[4] Girardello, L., Petrini, M., Porrati, M., and Zaffaroni, A. 1998. Novel local CFT and exact results on perturbations of N = 4 superYang Mills from AdS dynamics. J. High Energy Phys., 9812, 022.CrossRef Google Scholar

[5] Girardello, L., Petrini, M., Porrati, M., and Zaffaroni, A. 2000. The supergravity dual of N = 1 Super Yang-Mills theory.Nucl. Phys., B569, 451–69.Google Scholar

[6] Girardello, L., Petrini, M., Porrati, M., and Zaffaroni, A. 1999. Confinement and condensates without fine tuning in supergravity duals of gauge theories. J. High Energy Phys., 9905, 026.CrossRef Google Scholar

[7] Constable, Neil R., and Myers, Robert C. 1999. Exotic scalar states in the AdS/CFT correspondence.J. High Energy Phys., 9911, 020.CrossRef Google Scholar

[8] Babington, J., Erdmenger, J., Evans, Nick J., Guralnik, Z., and Kirsch, I. 2004. Chiral symmetry breaking and pions in nonsupersymmetric gauge/gravity duals.Phys. Rev., D69, 066007.Google Scholar

[9] Del Debbio, Luigi, Lucini, Biagio, Patella, Agostino, and Pica, Claudio. 2008. Quenched mesonic spectrum at largeN. J. High Energy Phys., 0803, 062.CrossRef Google Scholar

[10] Filev, Veselin G., Johnson, Clifford V., Rashkov, R. C., and Viswanathan, K. S. 2007. Flavoured large N gauge theory in an external magnetic field.J. High Energy Phys., 0710, 019.CrossRef Google Scholar

[11] Sakai, Tadakatsu, and Sugimoto, Shigeki. 2005. Low energy hadron physics in holographic QCD.Prog. Theor. Phys., 113, 843–882.CrossRef Google Scholar

[12] Sakai, Tadakatsu, and Sugimoto, Shigeki. 2005. More on a holographic dual of QCD.Prog. Theor. Phys., 114, 1083–1118.CrossRef Google Scholar

[13] Evans, Nick, and Threlfall, Ed. 2007. Quark mass in the Sakai-Sugimoto model of chiral symmetry breaking. ArXiv:0706.3285.

[14] Erdmenger, Johanna, Evans, Nick, Kirsch, Ingo, and Threlfall, Ed. 2008. Mesons in gauge/gravity duals - a review.Eur. Phys. J., A35, 81–133.

[15] Erlich, Joshua, Katz, Emanuel, Son, Dam T., and Stephanov, Mikhail A. 2005. QCD and a holographic model of hadrons.Phys. Rev. Lett., 95, 261602.CrossRef Google Scholar

[16] Da Rold, Leandro, and Pomarol, Alex. 2005. Chiral symmetry breaking from five dimensional spaces.Nucl. Phys., B721, 79–97.Google Scholar

[17] Shifman, Mikhail A., Vainshtein, A. I., and Zakharov, Valentin I. 1979. QCD and resonance physics: sum rules.Nucl. Phys., B147, 385–447.Google Scholar

[18] Karch, Andreas, Katz, Emanuel, Son, Dam T., and Stephanov, Mikhail A. 2006. Linear confinement and AdS/QCD.Phys. Rev., D74, 015005.Google Scholar

[19] Donoghue, J. F., Golowich, E., and Holstein, Barry R. 1992. Dynamics of the Standard Model. Cambridge Monograph on Particle Physics, Nuclear Physics and Cosmology,Vol. 2, Cambridge University Press, 2nd edition, 2014.Google Scholar

[20] Gubser, Steven S. 1999. Dilaton driven confinement. ArXiv:hep-th/9902155.

[21] Johnson, Clifford V., Peet, Amanda W., and Polchinski, Joseph. 2000. Gauge theory and the excision of repulson singularities.Phys. Rev., D61, 086001.Google Scholar

[22] Witten, Edward. 1979. Current algebra theorems for the U (1) Goldstone boson.Nucl. Phys., B156, 269.CrossRef Google Scholar

[23] 't Hooft, Gerard. 1986. How instantons solve the U (1) problem.Phys. Rep., 142, 357–387.CrossRef Google Scholar

[24] Barbon, Jose L. F., Hoyos-Badajoz, Carlos, Mateos, David, and Myers, Robert C. 2004. The holographic life of the eta-prime.J. High Energy Phys., 0410, 029.CrossRef Google Scholar

[25] Armoni, Adi. 2004. Witten-Veneziano from Green-Schwarz.J. High Energy Phys., 0406, 019.CrossRef Google Scholar

[26] Gell-Mann, Murray, Oakes, R. J., and Renner, B. 1968. Behaviour of current divergences under SU(3) x SU(3).Phys. Rev., 175, 2195–2199.CrossRef Google Scholar

[27] Evans, Nick J., and Shock, Jonathan P. 2004. Chiral dynamics from AdS space.Phys. Rev., D70, 046002.Google Scholar

[28] Bali, Gunnar, and Bursa, Francis. 2007. Meson masses at large Nc. Proceedings of Science, ArXiv: 0708.3427.

[29] Bali, Gunnar S., Bursa, Francis, Castagnini, Luca, Collins, Sara, Del Debbio, Luigi, et al. 2013. Mesons in large-N QCD.J. High Energy Phys., 1306, 071.CrossRef Google Scholar

[30] Albash, Tameem, Filev, Veselin G., Johnson, Clifford V., and Kundu, Arnab. 2008. Finite temperature large N gauge theory with quarks in an external magnetic field.J. High Energy Phys., 0807, 080.CrossRef Google Scholar

[31] Erdmenger, Johanna, Meyer, Rene, and Shock, Jonathan P. 2007. AdS/CFT with flavour in electric and magnetic Kalb-Ramond fields.J. High Energy Phys., 0712, 091.CrossRef Google Scholar

[32] Burrington, Benjamin A., Kaplunovsky, Vadim S., and Sonnenschein, Jacob. 2008. Localized backreacted flavor branes in holographic QCD.J. High Energy Phys., 0802, 001.CrossRef Google Scholar

[33] Gürsoy, Umut, Kiritsis, Elias, Mazzanti, Liuba, Michalogiorgakis, Georgios, and Nitti, Francesco. 2011. Improved holographic QCD. In From Gravity to Thermal Gange Theories: the AdS/CFT Correspondence., pp. 79–146. Lecture Notes in Phys.Google Scholar

[34] Brodsky, S. J., and de Teramond, G. F. 2004. Light-front hadron dynamics and AdS/CFT correspondence. Phys. Lett., B582, 211–221.Google Scholar

[35] Brodsky, S. J., and de Teramond, G. F. 2005. Hadronic spectrum of a holographic dual of QCD.Phys. Rev. Lett., 94, 201601.Google Scholar

[36] Brodsky, S. J., and de Teramond, G. F. 2009. Light-front holography: A first approximation to QCD.Phys. Rev. Lett., 102, 081601.Google Scholar

[37] Witten, Edward. 1998. Baryons and branes in anti-de Sitter space.J. High Energy Phys., 9807, 006.Google Scholar

[38] Csaki, Csaba, Ooguri, Hirosi, Oz, Yaron, and Terning, John. 1999. Glueball mass spectrum from supergravity. J. High Energy Phys., 9901, 017.CrossRef Google Scholar

[39] de Mello Koch, Robert, Jevicki, Antal, Mihailescu, Mihail, and Nunes, Joao P. 1998. Evaluation of glueball masses from supergravity.Phys. Rev., D58, 105009.Google Scholar

[40] Brower, Richard C., Mathur, Samir D., and Tan, Chung-I. 2000. Glueball spectrum for QCD from AdS supergravity duality.Nucl. Phys., B587, 249–276.Google Scholar

[41] Polchinski, Joseph, and Strassler, Matthew J. 2002. Hard scattering and gauge/string duality. Phys. Rev. Lett., 88, 031601.CrossRef Google Scholar PubMed

[42] Polchinski, Joseph, and Strassler, Matthew J. 2003. Deep inelastic scattering and gauge/string duality.J. High Energy Phys., 0305, 012.CrossRef Google Scholar

[43] Brower, Richard C., Polchinski, Joseph, Strassler, Matthew J., and Tan, Chung-I. 2007. The pomeron and gauge/string duality.J. High Energy Phys., 0712, 005.CrossRef Google Scholar

[44] Chernodub, M. N. 2010. Superconductivity of QCD vacuum in strong magnetic field.Phys. Rev., D82, 085011.Google Scholar

[45] Nielsen, N.K., and Olesen, P. 1978. An unstable Yang-Mills field mode.Nucl. Phys., B144, 376.CrossRef Google Scholar

[46] Bu, Yan-Yan, Erdmenger, Johanna, Shock, Jonathan P., and Strydom, Migael. 2013. Magnetic field induced lattice ground states from holography.J. High Energy Phys., 1303, 165.CrossRef Google Scholar

[47] Donos, Aristomenis, and Gauntlett, Jerome P. 2013. On the thermodynamics of periodic AdS black branes.J. High Energy Phys., 1310, 038.CrossRef Google Scholar

[48] Callebaut, N., Dudal, D., and Verschelde, H. 2013. Holographic rho mesons in an external magnetic field.J. High Energy Phys., 1303, 033.CrossRef Google Scholar

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13 - QCD and holography: confinement and chiral symmetry breaking

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