1 / 39

Fractal and Pseudopgaped Superconductors: theoretical introduction

Mikhail Feigel’man L.D.Landau Institute, Moscow. Fractal and Pseudopgaped Superconductors: theoretical introduction. Based on the results obtained in collaboration with Lev Ioffe and Emil Yuzbashyan Rutgers Vladimir Kravtsov ICTP Trieste

havyn
Download Presentation

Fractal and Pseudopgaped Superconductors: theoretical introduction

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Mikhail Feigel’man L.D.Landau Institute, Moscow Fractal and Pseudopgaped Superconductors: theoretical introduction Based on the results obtained in collaboration with Lev Ioffe and Emil Yuzbashyan Rutgers Vladimir Kravtsov ICTP Trieste Emilio Cuevas Murcia Univ. Publicationsrelevant to this talk: Phys Rev Lett.98, 027001(2007) (M.F.,L. Ioffe,V. Kravtsov, E.Yuzbashyan) Annals of Physics325, 1368 (2010) (M.F.,L.Ioffe, V.Kravtsov, E.Cuevas) Related publications: Phys. Rev. B 82, 184534(2010) (M.F. L.Ioffe, M. Mezard) Nature Physics 7, 239 (2011) (B.Sacepe,T.Doubochet,C.Chapelier,M.Sanquer, M.Ovadia,D.Shahar, M. F., L..Ioffe)

  2. Plan of the talk • Introduction: why new theory is needed? • Fractal superconductivity at the localization edge - sketch of the derivation - main features 3. Superconductivity with pseudogap - origin of the psedogap - development of the superconductive correlations - qualitative features • For the next steps (effects of quantum fluctuations) see the talk by Lev Ioffe: - S-I transition and insulating state - quantum phase slips within pseudogap model

  3. Superconductivity v/s Localization • Coulomb-induced suppression of Tc in uniform films “Fermionic mechanism” Yu.Ovchinnikov (1973, wrong sign) Mayekawa-Fukuyama (1983) A.Finkelstein (1987)Yu.Oreg & A. Finkelstein (1999) • Granular systems with Coulomb interaction K.Efetov (1980) M.P.A.Fisher et al (1990)“Bosonic mechanism” • Competition of Cooper pairing and localization (no Coulomb) Imry-Strongin, Ma-Lee, Kotliar-Kapitulnik,Bulaevskii-Sadovskii(mid-80’s) Ghosal, Randeria, Trivedi 1998-2001

  4. We consider amorphous systems with direct S-I transition Gap is NOT suppressed at the transition

  5. Bosonic mechanism: Control parameter Ec = e2/2C 1.Grains are needed, but we don’t have 2.SIT is actually not seen in arrays in magnetic field !

  6. Main challenges from exp. data • In some materials SC survives up to very high resistivity values. No structural grains are found there. • Preformed electron pairs are detected in the same materials both above Tc and at very low temp. on insulating side of SIT - by STM study in SC state - by the measurement of the activated R(T) ~ exp(T0/T) on insulating side

  7. SC side: local tunneling conductance Nature Physics7, 239 (2011)

  8. Superconductive state near SIT is very unusual: • the spectral gap appears much before (with T decrease) than superconductive coherence does • Coherence peaks in the DoS appear together with resistance vanishing • Distribution of coherence peaks heights is very broad near SIT

  9. Class of relevant materials • Amorphously disordered (no structural grains) • Low carrier density ( around 1021 cm-3 at low temp.) Examples: amorphous InOxTiN thin films Possibly similar:Be (ultra thin films)NbNx B- doped diamond Bosonic v/s Fermionic scenario ? None of them is able to describe data on InOx and TiN : Both scenaria are ruled out by STM data in SC state

  10. Superconductivity v/s Localization • Coulomb-induced suppression of Tc in uniform films “Fermionic mechanism” Yu.Ovchinnikov (1973, wrong sign) Mayekawa-Fukuyama (1983) A.Finkelstein (1987)Yu.Oreg & A. Finkelstein (1999) • Granular systems with Coulomb interaction K.Efetov (1980) M.P.A.Fisher et al (1990)“Bosonic mechanism” • Competition of Cooper pairing and localization (no Coulomb) Imry-Strongin, Ma-Lee, Kotliar-Kapitulnik,Bulaevskii-Sadovskii(mid-80’s) Ghosal, Randeria, Trivedi 1998-2001

  11. Superconductive transition at the mobility edge

  12. Theoretical model (3D) Simplest BCS attraction model, butfor critical (or weakly localized) electron eigenstates H = H0 - g ∫ d3rΨ↑†Ψ↓†Ψ↓Ψ↑ Basis of exact eigenfunctions of free electrons in random potential Ψ= ΣcjΨj (r) S-I transition atδL≈ Tc M. Ma and P. Lee (1985) : We will find that SC state is compatible withδL >> Tc

  13. Why do anyone may need analytical theory for S-I transition? • Low-temperature superconductivity is the nontrivial result of a weak interaction: Tc ~ (10-4 - 10-3) EF • It leads to relatively long coherence length ξ >> lattice constant • Thus straightforward computer simulation of interacting problem in relevant parameter range is impossible • Combination of analytical theory and numerical results might be very useful

  14. Mean-Field Eq. for Tc

  15. Fractality of wavefunctions 4 IPR: Mi = dr d2 ≈ 1.3 in 3D l is the short-scale cut-off length 3D Anderson model: γ = 0.57

  16. 3D Anderson model: long evolution from diffusive metal to the critical point E.Cuevas and V.Kravtsov, Phys.Rev B76 (2007) “Box distribution”: critical disorder strength Wc = 16.5 W=10 W=5 W=2

  17. Modified mean-field approximation for critical temperature Tc this Tc is higher than BCS value ! For small

  18. Alternative method to find Tc:Virial expansion(A.Larkin & D.Khmelnitsky 1970)

  19. Tc from 3 different calculations Modified MFA equation leads to: BCS theory: Tc = ωD exp(-1/ λ)

  20. Neglected so far : off-diagonal terms Non-pair-wise terms with 3 or 4 different eigenstates were omitted To estimate the accuracy we derived effective Ginzburg -Landau functional taking these terms into account W=∫<δa(r)δa(r’)>dr’ Parameters a, b, C and W do not contain fractal exponents

  21. Can we understand increase of Tc by disorder within regularperturbative approach ? Yes: - for 2D case without Coulomb interaction (only Cooper int.) Talk by Vladimir Kravtsov at KITP, Santa Barbara, 13 Sept.2010 “Can disorder increase superconducting Tc?” • for 2D case with short-range repulsion and • Cooper interaction I.Burmistrov, I. Gornyi and A. Mirlin arXiv: 1102.3323 “Enhancement of superconductivity by Anderson localization” Renormalization Group approach

  22. Order parameter in real space for ξ = ξk SC fraction =

  23. Tunnelling DoS Average DoS: Asymmetry in local DoS:

  24. Superconductivity at the Mobility Edge: major features • Critical temperature Tcis well-defined through the wholesystem in spite of strong Δ(r)fluctuations • Local DoS strongly fluctuates in real space; it results in asymmetric tunnel conductance G(V,r) ≠ G(-V,r) • Both thermal (Gi) and mesoscopic (Gid) fluctuational parameters of the GL functional are of order unity

  25. What to do with really thin films ? Where are no Anderson transition in 2D But localization length Lloc ~ exp(π g) g = h/e2Rsqr varies very sharply in the region g ~ 1 where crossover from weakto strong localization takes place Hypotetically the same kind of analysis we did for 3D can be adopted for 2D case But it was not done yet

  26. Superconductive state with a pseudogap

  27. Parity gap in ultrasmall grains Local pairing energy ------- ------- EF --↑↓-- --  ↓-- K. Matveev and A. Larkin 1997 No many-body correlations Correlations between pairs of electrons localized in the same “orbital”

  28. Parity gap for Anderson-localized eigenstates Energy of two single-particle excitations after depairing: ΔP plays the role of the activation gap

  29. Activation energy TI from Shahar-Ovadyahu exper. (1992) and fit to the theory The fit was obtained with single fitting parameter Example of consistent choice: = 400 K = 0.05 Similar fit with naïve exponent d=3 instead of d2 = 1.3 fails undoubtedly

  30. Tcversus Pseudogap Annals of Physics325, 1368 (2010) Superconductive transition exists even at δL >> Tc0

  31. Correlation functionM(ω) No saturation at ω < δL : M(ω) ~ ln2 (δL /ω) (Cuevas & Kravtsov PRB,2007) Superconductivity with Tc << δL is possible This region was not noticed previously only with weak coupling ! Here “local gap” exceeds SC gap :

  32. Single-electron states suppressed by pseudogap ΔP >> Tc “Pseudospin” approximation Effective number of interacting neighbours

  33. Qualitative features of “Pseudogaped Superconductivity”: • STM DoS evolution with T • Double-peak structure in point-contact conductance • Nonconservation of the full spectral weight across Tc eV1 = ΔP + Δ 2eV2 = 2 Δ V2 << V1 near SIT Ktot(T) Tc Δp T

  34. Spectral weight of high-ω conductivity constant (T-independent) in BCS Pseudogap superconductor with ΔP >> Δ

  35. Major unresolved theoretical problem with the developed approach: what happens to Coulomb repulsion?

  36. Coulomb enchancement near mobility edge ?? Normally, Coulomb interaction is overscreened, with universal effective coupling constant ~ 1 Condition of universal screening: Example of a-InOx : 0 e2kF ~ 5 104 K deeply in insulator state of InOx Effective Coulomb potential is weak if i.e. forκ> 300

  37. To be explained: Have been discussed in this talk: Generalized mean-field – like theory of superconductive state for critical or weakly localized single-electron states • Activated R(T) on the insulating side close to SIT • Strong fluctuations of coherence peak heights on the superconducting side • Nature of the SIT within pseudogap model See next talk for the results beyond MFA

More Related