PseudoGap Superconductivity and Superconductor-Insulator transition
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Transcript of PseudoGap Superconductivity and Superconductor-Insulator transition
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PseudoGap Superconductivity and Superconductor-Insulator transition
In collaboration with:
Vladimir Kravtsov ICTP Trieste Emilio Cuevas University of Murcia
Lev Ioffe Rutgers University Marc Mezard Orsay University
Mikhail Feigel’manL.D.Landau Institute, Moscow
Short publication: Phys Rev Lett. 98, 027001 (2007)
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Superconductivity v/s Localization
• Granular systems with Coulomb interactionK.Efetov 1980 et al “Bosonic mechanism”• Coulomb-induced suppression of Tc in
uniform films “Fermionic mechanism”A.Finkelstein 1987 et al
• Competition of Cooper pairing and localization (no Coulomb)
Imry-Strongin, Ma-Lee, Kotliar-Kapitulnik, Bulaevsky-Sadovsky(mid-80’s)Ghosal, Randeria, Trivedi 1998-2001
There will be no grains and no Coulomb in this talk !
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Bosonic mechanism:
Control parameter
Ec = e2/2C
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Plan of the talk1. Motivation from experiments2. BCS-like theory for critical eigenstates - transition temperature - local order parameter3. Superconductivity with pseudogap - transition temperature v/s pseudogap 4. Quantum phase transition: Cayley tree5. Conclusions and open problems
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Example: Disorder-driven S-I transition in TiN thin films
T.I.Baturina et al Phys.Rev.Lett 99 257003 2007
Specific Features of Direct SIT:
Insulating behaviour of the R(T) separatrix
On insulating side of SIT, low-temperature resistivity is activated: R(T) ~ exp(T0/T)
Crossover to VRH at higher temperatures
Seen in TiN, InO, Be (extra thin) – all areamorphous, with low electron density
There are other types of SC suppression by disorder !
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Strongly insulating InO and nearly-critical TiN
.
Kowal-Ovadyahu 1994 Baturina et al 2007
0 2 4 6 8 10 12 14 16 18
9
10
11
12
13
14
15
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17
I2
10 1 0.4 0.2T [K]
0.1 0.06
ln(R
[Ohm
])
1/T[K]
I2: T0 = 0.38 KR0 = 20 k
d = 5 nm
0 1 2 3 4
9
10
11
12
13
14
15
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17
ln(R
[Ohm
])
1/(T[K])1/2
d = 20 nmT0 = 15 KR0 = 20 k
What is the charge quantum ? Is it the same on left and on right?
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Giant magnetoresistance near SIT(Samdanmurthy et al, PRL 92, 107005 (2004)
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Experimental puzzle: Localized Cooper pairs
.
D.Shahar & Z.Ovadyahuamorphous InO 1992
V.Gantmakher et al InOD.Shahar et al InOT.Baturina et al TiN
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Bosonic v/s Fermionic scenario ?
None of them is able to describe data on InOx and TiN
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Major exp. data calling for a new theory
• Activated resistivity in insulating a-InOx
D.Shahar-Z.Ovadyahu 1992,
V.Gantmakher et al 1996
T0 = 3 – 15 K• Local tunnelling data B.Sacepe et al 2007-8
• Nernst effect above Tc P.Spathis, H.Aubin et al 2008
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Phase Diagram
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Theoretical model
Simplest BCS attraction model, but for critical (or weakly)
localized electrons
H = H0 - g ∫ d3r Ψ↑†Ψ↓
†Ψ↓Ψ↑
Ψ = Σ cj Ψj (r) Basis of localized eigenfunctions
M. Ma and P. Lee (1985) : S-I transition at δL ≈ Tc
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Superconductivity at the Localization Threshold: δL → 0
Consider Fermi energy very close to the mobility edge:single-electron states are extended but fractal and populate small fraction of the whole volume
How BCS theory should be modified to account
for eigenstate’s fractality ?Method: combination of analitic theory and numerical data for Anderson mobility edge model
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Mean-Field Eq. for Tc
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3D Anderson model: γ = 0.57
D2 ≈ 1.3 in 3D
Fractality of wavefunctions
IPR: Mi = 4dr
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Modified mean-field approximation for critical temperature Tc
For small this Tc is higher than BCS value !
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Alternative method to find Tc:Virial expansion
(A.Larkin & D.Khmelnitsky 1970)
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Tc from 3 different calculations
Modified MFA equationleads to:
BCS theory: Tc = ωD exp(-1/ λ)
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Order parameter in real space
for ξ = ξk
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Fluctuations of SC order parameter
SC fraction =
Higher moments:
prefactor ≈ 1.7 for γ = 0.57
With Prob = p << 1 Δ(r) = Δ , otherwise Δ(r) =0
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Tunnelling DoS
Asymmetry in local DoS:
Average DoS:
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Neglected : 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
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Superconductivity at the Mobility Edge: major features
- Critical temperature Tc is well-defined through the whole system 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
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Superconductivity with Pseudogap Now we move Fermi- level into the range of localized eigenstates
Local pairing in addition tocollective pairing
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1. Parity gap in ultrasmall grains K. Matveev and A. Larkin 1997
No many-body correlations
Local pairing energy
Correlations between pairs of electrons localized in the same “orbital”
-------------- EF
--↑↓---- ↓--
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2. Parity gap for Anderson-localized eigenstates
Energy of two single-particle excitations after depairing:
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P(M) distribution
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Activation energy TI from Shahar-Ovadyahu exp. and fit to theory
The fit was obtained with single fitting parameter
= 0.05 = 400 K
Example of consistent choice:
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Critical temperature in the pseudogap regime
Here we use M(ω) specific for localized states
MFA is OK as long as
MFA:
is large
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Correlation function M(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 found previously
Here “local gap”exceeds SC gap :
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Critical temperature in the pseudogap regime
We need to estimate
MFA:
It is nearly constant in a very broad range of
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Tc versus Pseudogap
Transition exists even at δL >> Tc0
Virial expansion results:
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Single-electron states suppressed by pseudogap
Effective number of interacting neighbours
“Pseudospin” approximation
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Third Scenario• Bosonic mechanism: preformed Cooper pairs +
competition Josephson v/s Coulomb – S I T in arrays• Fermionic mechanism: suppressed Cooper attraction, no
paring – S M T
• Pseudospin mechanism: individually localized pairs - S I T in amorphous media
SIT occurs at small Z and lead to paired insulator
How to describe this quantum phase transition ? Cayley tree model is solved (L.Ioffe & M.Mezard)
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Qualitative features of “Pseudogaped Superconductivity”:
• STM DoS evolution with T
• Double-peak structure in point-contact conuctance
• Nonconservation of full spectral weight across Tc
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Superconductor-Insulator Transition
Simplified model of competition between random local energies (ξiSi
z term) and XY coupling
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Phase diagram
Superconductor
Hopping insulator
g
Temperature
Energy
RSB state
Full localization:Insulator withDiscrete levels
MFA line
gc
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Fixed activation energy is due to the absence of thermal bath at low ω
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Conclusions Pairing on nearly-critical states produces fractal
superconductivity with relatively high Tc but very small superconductive density
Pairing of electrons on localized states leads to hard gap and Arrhenius resistivity for 1e transport
Pseudogap behaviour is generic near S-I transition, with “insulating gap” above Tc
New type of S-I phase transition is described (on Cayley tree, at least). On insulating side activation of pair
transport is due to ManyBodyLocalization threshold
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Coulomb enchancement near mobility edge ??
Condition of universal screening:
Normally, Coulomb interaction is overscreened, with universal effective coupling constant ~ 1
Example of a-InOx
Effective Couloomb potential is weak:
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Class of relevant materials
• Amorphously disordered (no structural grains)• Low carrier density ( around 1021 cm-3 at low temp.)Examples: InOx NbNx thick films or bulk (+ B-doped Diamond?) TiN thin films Be, Bi (ultra thin films)