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Vortex liquid in electromagnetically superconducting vacuum due to strong magnetic field: numerical lattice results V. V. Braguta, P. V. Buividovich, M. N. Chernodub, A. Yu. Kotov and M. I. Polikarpov Based on: arXiv:1008.1055, arXiv:1101.0117, arXiv:1111.4401, arXiv:1104.3767, arXiv:1104.4404 + ongoing work Superconductivity Type I Type II I. Any superconductor has zero electrical DC resistance II. Any superconductor is an enemy of the magnetic field: 1) weak magnetic fields are expelled by all superconductors (the Meissner effect) 2) strong enough magnetic field always kills superconductivity The claim: In a background of strong enough magnetic field the vacuum becomes a superconductor. The superconductivity emerges in empty space. Literally, “nothing becomes a superconductor”. M.Ch., arXiv:1008.1055, arXiv:1101.0117 The claim seemingly contradicts textbooks which state that: 1. Superconductor is a material (= a form of matter, not an empty space) 2. Weak magnetic fields are suppressed by superconductivity 3. Strong magnetic fields destroy superconductivity General features Some features of the superconducting state of vacuum: 1. spontaneously emerges above the critical magnetic field or Bc ≃ 1016 Tesla = 1020 Gauss 2 2 2 eBc≃ mρ ≃ 31 mπ ≃ 0.6 GeV 2. usual Meissner effect does not exist 3. perfect conductor (= zero DC resistance) in one spatial dimension (along the axis of the magnetic field) 4. insulator in other (perpendicular) directions Too strong critical magnetic field? eBc≃ mρ ≃ 31 mπ ≃ 0.6 GeV 2 2 2 Over-critical magnetic fields (of the strength B ~ 2...3 Bc) may be generated in ultraperipheral heavy-ion collisions (duration is short, however – detailed calculations are required) LHC eBc LHC eBc RHIC ultraperipheral W. T. Deng and X. G. Huang, Phys.Rev. C85 (2012) 044907 A. Bzdak and V. Skokov, Phys.Lett. B710 (2012) 171 + Vladimir Skokov, private communication. Approaches to the problem: 0. General arguments; 1. Effective bosonic model for electrodynamics of ρ mesons based on vector meson dominance [M.Ch., arXiv:1008.1055] 2. Effective fermionic model (the Nambu-Jona-Lasinio model) [M.Ch., arXiv:1101.0117] 3. Nonperturbative effective models based on gauge/gravity duality (AdS/CFT) [Erdmenger, Kerner, Strydom (Munich, Germany), arXiv:1106.4551] [Callebaut, Dudal, Verschelde (Gent U., Belgium), arXiv:1105.2217] 5. Numerical simulation of vacuum ITEP Lattice Group, Moscow, arXiv:1104.3767 + (this talk) Pairing of quarks in strong magnetic field Well-known “magnetic catalysis”: S.P. Klevansky and R. H. Lemmer ('89); H. Suganuma and T. Tatsumi ('91); V. P. Gusynin, V. A. Miransky and I. A. Shovkovy ('94, '95, '96,...) attractive channel: spin-0 flavor-diagonal states enhances chiral symmetry breaking 0 B This talk: attractive channel: spin-1 flavor-offdiagonal states (quantum numbers of ρ mesons) electrically charged condensates: leads to electromagnetic superconductivity 0 B Bc Key players: ρ mesons and vacuum - ρ mesons: • electrically charged (q= ±e) and neutral (q=0) particles • spin: s=1, vector particles • quark contents: ρ+ =ud, ρ– =du, ρ0 =(uu-dd)/21/2 • mass: mρ=775.5 MeV • lifetime: τρ=1.35 fm/c (very short: size of the ρ meson is 0.5 fm) - vacuum: QED+QCD, zero tempertature and density Naïve qualitative picture of quark pairing in the electrically charged vector channel: ρ mesons - Energy of a relativistic particle in the external magnetic field Bext: momentum along the magnetic field axis nonnegative integer number projection of spin on the magnetic field axis (the external magnetic field is directed along the z-axis) - Masses of ρ mesons and pions in the external magnetic field becomes heavier becomes lighter - Masses of ρ mesons and pions: Condensation of ρ mesons The ρ± mesons become massless and condense at the critical value of the external magnetic field masses in the external magnetic field Kinematical impossibility of dominant decay modes The pion becomes heavier while the rho meson becomes lighter - The decay stops at certain value of the magnetic field - A similar statement is true for Structure of the condensates In terms of quarks, the state implies Depend on transverse coordinates only (the same structure of the condensates in the Nambu-Jona-Lasinio model) - The absolute value of the condensate: Second order (quantum) phase transition, critical exponent = 1/2 Condensates of ρ mesons, solutions Superconducting condensate (charged rho mesons) Superfluid condensate B = 1.01 Bc (neutral rho mesons) New objects, topological vortices, made of the rho-condensates The phases of the rho-meson fields wind around vortex centers, at which the condensates vanish. similar results in holographic approaches by M. Ammon, Y. Bu, J. Erdmenger, P. Kerner, J. Shock, M. Strydom (2012) Anisotropic superconductivity (via an analogue of the London equations) - Apply a weak electric field E to an ordinary superconductor - Then one gets accelerating electric current along the electric field: [London equation] - In the QCDxQED vacuum, we get an accelerating electric current along the magnetic field B: ( ) Written for an electric current averaged over one elementary (unit) rho-vortex cell (similar results in NJL) Numerical simulations in the magnetic field background V.Braguta, P. Buividovich, A. Kotov, M. Polikarpov, M.Ch., arXiv:1104.3767 condensate Quenched SU(2) + overlap fermions. Spacings: a ~ 0.1 fm 4 4 Lattices: L ~ (2 fm) Theory: magnetic field [qualitatively realistic vacuum, quantitative results may receive corrections (20%-50% typically)] Ongoing discussion: negative results by Y. Hidaka, A. Yamamoto, arXiv:1209.0007; counterarguments by M. Ch., arXiv:1209.3587. The ρ meson condensate is difficult to observe in lattice simulations due to strong inhomogeneities of the ground state 1) The phase of the ρ meson condensate is a lively function of the transverse coordinates (x,y): its average is zero (analytically). But the condensate itself is nonzero. 2) The phase of the condensate jumps by 2π around the ρ vortices. 3) The ρ vortices move even within the same configuration (= neither straight nor static) Can we visualise the ρ meson condensate? Inspiration: G.S. Bali, K. Schilling, C. Schlichter, hep-lat/9409005 (PRD). Observation of chromoelectric flux (confining) tubes between quark and antiquark on the lattice Observable: The color field strength tensor in the presence of the Wilson loop (quark source) “W” Observables: The ρ meson field ; in the background of magnetic field B and SU(2) gauge configuration ASU(2) transforms as a charged field under the electromagnetic U(1): Normalized energy: ; Normalized electric current: Vortex density (2π singularities in the phase of the ρ meson field): Expectations: [J. Van Doorsselaere, H. Verschelde, B M. Ch, arXiv:1111.4401] Ground state: hexagonal lattice arrangement of the vortices along the magnetic field B However: other lattice arrangements (square, rhombic, etc) are very close (0.1%) in energy the hexagonal order may be destroyed by fluctuations. Expected reality: quantum fluctuations move and disturb vortices. They are no more straight parallel and static. Normalized energy of the ρ meson condensate in the transverse plane. Check x-y slice at fixed time t and distance z Instead of a regular lattice structure we see an irregular vortex pattern (vortex liquid?) The vortices move as we move the slice. Normalized energy of the ρ meson condensate along the magnetic field. Check x-z slice at fixed time t and coordinate y Vortices are not straight and static: they are curvy moving one-dimensional (in 3d) structures. Electric currents around vortices: Theory: It is indeed a vortex liquid! Vortex density-density correlators: (similar pictures for other values of the magnetic field strength) Real superconductors possess a vortex phase: Nishizaki, Kobayashi, Supercond. Sci. Technol. 13 (2000) 1 Conclusions ● In a sufficiently strong magnetic field condensates with ρ meson quantum numbers are formed spontaneously. The vacuum (= no matter present, = empty space, = nothing) ● becomes electromagnetically superconducting. ● ● ● ● ● ● The superconductivity is anisotropic: the vacuum behaves as a perfect conductor only along the axis of the magnetic field. New type of topological defects,''ρ vortices'', emerge. The ground state of ρ vortices is the Abrikosov-type lattice in transverse (w.r.t. the axis of magnetic field) directions. The liquid of the vortices is seen in lattice simulations. (Signatures of) the superconducting phase can be checked at LHC? Backup Topological structure of the ρ mesons condensates Simplest approach: Electrodynamics of ρ mesons - Lagrangian (based on vector dominance models): Nonminimal coupling leads to g=2 - Tensor quantities - Covariant derivative - Kawarabayashi-SuzukiRiadzuddin-Fayyazuddin relation - Gauge invariance [D. Djukanovic, M. R. Schindler, J. Gegelia, S. Scherer, PRL (2005)] Too quick for the condensate to be developed, but signatures may be seen due to instability of the vacuum state ρmeson vacuum state between the ions in ultraperipheral collisions B=0 “no condensate” vacuum state B > Bc instability due to magnetic field B > Bc rolling towards new vacuum state Emission of ρ mesons B=0 rolling back to “no condensate” vacuum state Anisotropic superconductivity (Lorentz-covariant form of the London equations) We are working in the vacuum, thus the transport equations may be rewritten in a Lorentz-covariant form: Electric current averaged over one elementary rho-vortex cell A scalar function of Lorentz invariants. In this particular model: Lorentz invariants: (slightly different form of κ function in NJL) If B is along x3 axis, then we come back to and