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@Nagoya U. Sept. 5, 2009 Naoto Nagaosa Department of Applied Physics

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Presentation on theme: "@Nagoya U. Sept. 5, 2009 Naoto Nagaosa Department of Applied Physics"— Presentation transcript:

1 Quantum transport phenomena with the edge channels in topological superconductors
@Nagoya U. Sept. 5, 2009 Naoto Nagaosa Department of Applied Physics The University of Tokyo and Cross-Correlated Materials Research Group, RIKEN Collaborators: Y. Tanaka, T. Yokoyama, A.V. Balatsky Phys. Rev. B (Rapid Communications) Vol (2009) Phys. Rev. Lett. Vol (2009) Phys. Rev. Lett. Vol (2009)

2 Analogy between chiral superconductor and QHS
Quantum Hall system Chiral superconductor Spontaneous T-symmetry breaking Topological integer ?? Chiral edge channels

3 Chiral p-wave superconductors
Sr2RuO4 Maeno (1994), Sigrist-Rice Spin-triplet p-wave Time-reversal symmetry broken Topological index for chirality Volovik related to the # of edge channels but not to

4 Andreev bound state in SRO
Maeno et al. (01) voltage compressible ground state V charge accumulation Furusaki-Matsumoto-Sigrist (2000) Current I

5 Majorana (real) Fermions
Usual (complex) fermions “half” of the usual (complex) fermion “real” fermion Chiral Majorana mode at the edge of spinless p+ip SC (A.Furusaki) c.f. Majorna zero energy bound state at vortex (Read-Green, Kitaev, Ivanov, D.H.Lee etc.)

6 2D topological insulator (Quantum Spin Hall system)
Time-reversal symmetric system Spin current instead of charge current Spin-orbit interaction helical edge channels Kane-Mele New topological matter Quantum Well of HgTe system Molenkamp-SC.Zhang

7 3D Topological insulator
3D generalization of QSH system Topological insulator helical edge channels odd number of 2D Dirac surface metal Robust against disorder - New state of matter From C.L.Kane’s homepage

8 Proximity effect of SC and topological insulator
Fu-Kane A B A B channels SC Ferro Chiral Majorana Ferro up Ferro down Chiral Fermion SC SC Helical Majorana Ferro Metal No channel

9 Non-centrosymmetric Superconductors
CePt3Si LaAlO3/SrTiO3 interface Bauer-Sigrist et al. Time-reversal Space-inversion Mixture of spin singlet and triplet pairings Possible helical superconductivity M. Reyren et al 2007

10 Edge modes of various systems
Majorana fermion robust susceptible Chiral Majorana Chiral Fermion Helical Majorana Spinless Fermion Helical Fermion Spinful Fermion 2-Spinful Fermion p+ip SC 5/2 FQH STI+SC 1/3 FQH Helical SC Ferro wire QSHS Q-wire Ladder

11 Purpose of this work Charge transport on the surface of topological insulator via chiral Majorana edge mode(CMM). Influence of magnetization on CMM. Tunneling conductance in N/FI/S junction Josephson current in S/FI/S junctions Helical Majorana edge modes in non-centrosymmetric SC

12 Hamiltonian for the surface state of Topological insulator
m plays the role of vector potential N/TI/S N/TI/S

13 N/FI/S junction on top of TI (1) Dispersion of CMM a b c
Chiral Majorana mode N/FI/S junction on top of TI (1) x z y x Dispersion of CMM a Sign change by the direction of mz b c Chiral Majorana mode (CMM) appears as an Andreev bound state Change of velocity of Chiral Majorana mode (CMM) by m/mz

14 Normalized conductance has a peak at zero voltage
Chiral Majorana mode N/FI/S junction on top of TI(2) x z y x a b c Normalized conductance has a peak at zero voltage

15 CMM is also influence by my/mz
Chiral Majorana mode N/FI/S junction on top of TI (3) x z y x a b c c CMM is also influence by my/mz

16 S/FI/S junction on top of TI (1) CMMs a b c y x
Chiral Majorana mode S/FI/S junction on top of TI (1) y x sN: Transparency of the junction CMMs j: Phase difference a b c

17 S/FI/S junction on top of TI (2) a b c
y Anomalous current phase relation by mx a b c Anomalous current phase relation can be detected by interferometer

18 Non-centrosymmetric Superconductors
CePt3Si LaAlO3/SrTiO3 interface Bauer-Sigrist et al. Time-reversal Space-inversion Mixture of spin singlet and triplet pairings Possible helical superconductivity M. Reyren et al 2007

19 Rashba superconductor
Chiral base Both + and – bands are p+ip superconductor Frigeri et al. 2004 Fu-Kane, 2008 Proximity effect of 3D topological insulator and s-wave SC

20 Andreev bound state energy dispersion
Low energy limit Kramer’s pair of Majorana edge modes Helical edge modes appear only when

21 Angle resolved Andreev reflection
Normal metal Helical superconductor

22 Doppler shift induces spin current
Super current Normal metal Helical SC Magnetic field -0.4 0.4

23 Split electrons into fractions
8 pieces of fractions !! L R etc. harmonic oscillator Recombination of pieces robust susceptible Chiral Majorana Chiral Fermion Helical Majorana Spinless Fermion Helical Fermion Spinful Fermion 2-Spinful Fermion p+ip SC 5/2 FQH STI+SC 1/3 FQH Helical SC Ferro wire QSHS Q-wire Ladder

24 Conclusions Topological insulators and non-centrosymmetric SC with T-symmetry as new comers Manipulation of the Majorana fermion, Andreev reflection, and Josephson junction by magnetization direction  transport perpendicular to edge 3. Spintronics functions in superconductors     using helical edge channels 4. All kinds of edge channels - chiral, helical, Majorana, etc - electrons are split into 8 pieces - Recombine some of the pieces to produce a new state

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