“granular metals and superconductors”
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“Granular metals and superconductors” M. V. Feigel’man (L.D.Landau Institute, Moscow) ICTS Condensed matter theory school, Mahabaleshwar, India, Dec.2009 Lecture 1. Disordered metals: quantum corrections and scaling theory. Lecture 2. Granular metals - PowerPoint PPT PresentationTRANSCRIPT
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“Granular metals and superconductors” M. V. Feigel’man (L.D.Landau Institute, Moscow) ICTS Condensed matter theory school, Mahabaleshwar, India, Dec.2009
Lecture 1. Disordered metals: quantum corrections and scaling theory. Lecture 2. Granular metals
Lecture 3. Granular superconductors and Josephson Junction arraysLecture 4. Homogeneously disordered SC films and S-N arrays Lecture 5. Superconductivity in amorphous poor conductors:
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Lecture 1. Disordered metals: quantum
corrections and scaling theory Plan of the Lecture
1) Dimensionless conductance and its scaling2) Interference corrections to conductivity and
magnetoresistance3) Spin-orbit scattering and “anti-localization”
4) Aronov-Altshuler corrections due to e-e interaction 5) Fractal nature of critical wave-functions: is simple
scaling valid ?
Classical Reviews:
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A non-interacting electron moving in random potential
Quantum interference of scattering waves
Anderson localization of electrons
E
extended
localizedlocalized
extended
localized
critical
Ec
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Scaling theory (“gang of four”, 1979)
Metal:
Insulator:
A metal-insulator transition at g=gc is continuous (d>2).
Conductance changes when system size is changed.
All wave functions are localized below two dimensions!
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d ln g/d ln L = β(g)
β(g) = (d-2) – 1/g at g >>1 = ln g at g << 1
g(L) = const Ld-2 Classical (Drude) conductivity
This is for scattering on purely potential disorder
For strong Spin-Orbit scattering (-1/g) → (+1/2g)
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“Anti-localization” due to S-O
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e-e interaction corrections (Altshuler & Aronov)
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g(T): Full RG with AA corrections
β(g) = – 1/g – 1/g for potential scattering (g>> 1)
β(g) = +1/2g – 1/g for Spin-Orbital scattering (g >> 1)
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Science (2005)
Anti-localizing effect of interactions at large nv
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arXiv:0910.1338
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Fractality of critical wavefunctions in 3D
E. Cuevas and V. E. Kravtsov Phys. Rev. B 76, 235119 (2007)
Anderson Transitions F. Evers, A.D. MirlinRev. Mod. Phys. 80, 1355 (2008)
IPR:
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Critical eigenstates: 3D mobility edge
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Wavefunction’s correlations in insulating band
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2D v/s 3D: qualitative difference
• 2D weak localization: fractality is weak, 1-d2/d ~ 1/g << 1
• 3D critical point: strong fractal effects, 1-d2/d = 0.57
3D Anderson model (“box” distribution): Wc=16.5 but simple diffusive metal is realized at W < 2-3 only
P(V)
VHopping amplitude t W = V1/tV1
-V1
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Anderson localization
A non-interacting electron in a random potential may be localized.
Anderson (1957)
Gang of four (1979): scaling theory
Weak localization P.A. Lee, H. Fukuyama, A. Larkin, S. Hikami, ….
well-understood area in condensed-matter physics
Unsolved problems:
Theoretical description of critical points
Scaling theory for critical phenomena in disordered systems