Y. Tanaka Nagoya University, Japan Y. Asano Hokkaido University, Japan Y. Tanuma Akita University, Japan Alexander Golubov Twente University, The Netherlands.

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Presentation transcript:

Y. Tanaka Nagoya University, Japan Y. Asano Hokkaido University, Japan Y. Tanuma Akita University, Japan Alexander Golubov Twente University, The Netherlands Odd frequency pairing in superconducting heterostructures

Contents (1) What is odd-frequency pairing (2) Normal metal / Superconductor junctions (3) Ferromagnet/Superconductor junctions

Conventional Classification of Symmetry of Cooper pair Spin-singlet Cooper pair s-wave d-wave Spin-triplet Cooper pair Even Parity Odd Parity p-wave BCS Cuprate 3 HeSr 2 RuO 4

Odd-frequency pairing Fermi-Dirac statistics Symmetry of pair wave functions: even-frequency superconductivity odd-frequency superconductivity ()()   ( ω ), f( ω )  Berezinskii (1974): Spin-triplet s-wave Balatsky&Abrahams (1992): Spin-singlet p-wave Momentum x Spin x Frequency

Pair amplitude (pair correlation) Exchange of two electrons Fermi-Dirac statistics

Pair amplitude Exchange of time Even-frequency pairing (conventional pairing) Odd-frequency pairing

Symmetry of the pair amplitude Frequency ( time) Spin +(even)  odd) +(even)  odd) +(even) Orbital + symmetric,  anti-symmetric ESE ETO OTE OSO   singlet) Total      (odd) + (triplet) +  triplet) ESE (Even-frequency spin-singlet even-parity) ETO (Even-frequency spin-triplet odd-parity) OTE (Odd-frequency spin-triplet even-parity) Berezinskii OSO (Odd-frequency spin-singlet odd-parity) Balatsky, Abrahams   singlet) +(even)  (odd) BCS Cuprate 3 He Sr 2 RuO 4

Odd-frequency pairing state is possible in inhomogeneous superconductors even for conventional even-frequency paring in the bulk Broken spin rotation symmetry or spatial invariance symmetry can induce odd-frequency pairing state: - ferromagnet/superconducor junctions: Bergeret,Volkov&Efetov, non-uniform systems: Junctions: Tanaka&Golubov, 2007; Eschrig&Lofwander, 2007 Vortices: Yokoyama et al., 2008; Tanuma et al., 2009)

Contents (1) What is odd-frequency pairing (2) Ballistic normal metal junctions ( 3 ) Diffusive normal metal junctions (4 ) Ferromagnet/Superconductor junctions

Ballistic junction Y. Tanaka, A. Golubov, S. Kashiwaya, and M. Ueda Phys. Rev. Lett (2007) M. Eschrig, T. Lofwander, Th. Champel, J.C. Cuevas and G. Schon J. Low Temp. Phys (2007) Ballistic Normal metal (semi-infinite) Superconductor (semi-infinite)

Eilenberger equation ballistic normal metal S Form factor S N (explicitly denote direction of motion) Bulk state Quasiparticle function Pair amplitudes Only Pair potential

Normal metal spin-triplet p-wave superconductor

p x -wave component of ETO pair amplitude s-wave component of OTE pair amplitude (high-transparent) (low-transparent) Y. Tanaka, et al PRL (2007) ETO (Even-frequency spin-triplet odd-parity) OTE (Odd-frequency spin-triplet even-parity) Pair potential Symmetry of the bulk pair potential is ETO

Underlying physics Near the interface, even and odd-parity pairing states (pair amplitude) can mix due to the breakdown of the translational symmetry. The interface-induced state (pair amplitude) should be odd in frequency where the bulk pair potential has an even -frequency component since there is no spin flip at the interface. Fermi-Dirac statistics

Andreev bound states in inhomogeneous systems are manifestations of odd-frequency pairing amplitude Surface: Tanaka et al, 2007 Vortex : Tanuma et al, 2009 Andreev bound states Electron-like QP Hole-like QP Cooper pair Positive pair potential Negative pair potential Scattering direction of QP Phase change due to a vortex

Mid gap Andreev resonant (bound) state (MARS) Interface (surface) +ー Local density of state has a zero energy peak. (Sign change of the pair potential at the interface) Tanaka Kashiwaya PRL (1995), Rep. Prog. Phys (2000) Buchholz(1981) Hara Nagai(1986) Hu(1994) Matsumoto Shiba(1995) Ohashi Takada(1995) Hatsugai and Ryu (2002) + ー ー +

Y. Tanaka, Y. Tanuma and A.A.Golubov, Phys. Rev. B 76, (2007) Odd-frequency pairing state in N/S junctions (N finite length) Bounds state are formed in the normal metal

Ratio of the pair amplitude in the N region (odd/even) At some energy, odd-frequency component can exceed over even frequency one. Odd-frequency pairing Even-frequency pairing Hidden odd-frequency component in the s-wave superconductor junctions

Ratio of the pair amplitude at the N/S interface and the bound state level Bound states condition (Z=0) ( McMillan Thomas Rowell) Bound states are due to the generation of the odd-frequency Cooper pair amplitude Odd-frequency pairing Even-frequency pairing Y. Tanaka, Y. Tanuma and A.A. Golubov, PRB (2007)

(1) (2) (3) (4) ESE (Even-frequency spin-singlet even-parity) ETO (Even-frequency spin-triplet odd-parity) OTE (Odd-frequency spin-triplet even-parity) OSO (Odd-frequency spin-singlet odd-parity) Bulk state ESE (s,d x2-y2 -wave) ESE (d xy -wave) ETO (p x -wave) ETO (p y -wave) Sign change (MARS) No Yes Interface-induced symmetry (subdominant component ) Yes No ESE + (OSO) OSO +(ESE) OTE + (ETO) ETO + (OTE) Symmetry of the Cooper pair (No spin flip) Phys. Rev. Lett (2007) (1)(2)(3) (4)

Contents (1) What is odd-frequency pairing (2) Ballistic normal metal junctions ( 3 ) Diffusive normal metal junctions (4 ) Ferromagnet/Superconductor junctions

Impurity scattering effect Tanaka and Golubov, PRL. 98, (2007) Ballistic Normal metal Superconductor Diffusive Normal metal (DN) Superconductor Impurity scattering (isotropic) Only s-wave pair amplitude exists in DN (1)ESE (2)OTE ESE (Even-frequency spin-singlet even-parity) OSO (Odd-frequency spin-singlet odd-parity)

DN S Even frequency spin singlet even parity (ESE) pair potential Even frequency spin singlet s-wave (ESE) pair is induced in DN. ESE pair /ESE pair potential

DN +ー P x -wave case New type of proximity effect Odd frequency spin triplet s-wave (OTE) pair is induced in DN Y.Tanaka, A.A.Golubov, Phys.Rev.Lett. 98, (2007)

Density of states in DN Conventional proximity effect with Even-frequency Cooper pair in DN Unconventional proximity effect with Odd-frequency Cooper pair in DN Tanaka&Kashiwaya, 2004

Symmetry of the pair potential Induced pair amplitude in DN  Even frequency spin singlet even parity (ESE) Even frequency spin triplet odd parity (ETO) Odd frequency spin triplet even parity (OTE) Odd frequency spin singlet odd parity (OSO)    ESE OTE ESE Summary of Proximity effect (diffusive normal metal, s-wave pairing state only)

How to detect odd-frequency paring amplitude: measuring electrical conductivity Asano, Tanaka, Golubov, Kashiwaya, PRL 99, (2007) Sr 2 RuO 4 Au :I+ Au :V+ Au :I- Au :V- Kashiwaya, Maeno 2007 Zero energy peak No Zero energy peak OTE proximity ESE proximity (conventional) OTE (Odd-frequency spin-triplet even-parity) ESE (Even-frequency spin-singlet even-parity)

Andreev bound states in inhomogeneous systems are manifestations of odd-frequency pairing amplitude Surface: Tanaka et al, 2007 Vortex : Tanuma et al, 2009 Andreev bound states Electron-like QP Hole-like QP Cooper pair Positive pair potential Negative pair potential Scattering direction of QP Phase change due to a vortex

Symmetry of the Cooper pair in a vortex core l ; angular momentum m ; vorticity bulk Center of the vortex core ESE (Even-frequency spin-singlet even-parity) ETO (Even-frequency spin-triplet odd-parity) OTE (Odd-frequency spin-triplet even-parity) OSO (Odd-frequency spin-singlet odd-parity Even Odd Even Odd Even Odd ESE (s-wave..) ESE ESE (s-wave..) ETO (chiral p-wave) OSO ETO OTE Yokoyama et al., Physical Review B, Vol. 78, , 2008

Difference of the angular momentum of the odd-frequency pair at the core center Tanuma, Hayashi, Tanaka Golubov Phys. Rev. Lett. 102, (2009). Angular momentum at the center of core; l+m l : angular momentum m : vorticity Chirality and vorticity: Y. Kato and N. Hayashi (2000, 2001,2002)

Contents (1) What is odd-frequency pairing (2) Ballistic normal metal junctions ( 3 ) Diffusive normal metal junctions ( 4 ) Ferromagnet/Superconductor junctions

_ Odd frequency spin-triplet s-wave pair Superconductor Ferromagnet Bergeret, Efetov, Volkov, (2001) Eschrig, Buzdin, Kadigrobov,Fominov, Radovic Generation of the odd-frequency pair amplitude in ferromagnet Odd-frequency pair amplitude (not pair potential) is generated in ferromagnet junctions spin-singlet s-wave pair +

Josephson current in S/HM/S Half metal : CrO 2 Keizer et.al., Nature (2006) Eschrig et. al., PRL(‘03) Theory in the clean limit Spin active interface Bergeret et. al., PRL(‘01), Kadigrobov et. al., Europhys Lett.(‘01) Lofwander and Eschrig, Nature Physics (2008)

Furusaki, Physica B(‘92), Asano, PRB(‘01) Advantages SNS, SFS, S/HM/S Parameters : exchange : spin-flip Recursive GF Y.Asano, Y. Tanaka, A.A.Golubov, Phys.Rev.Lett. 98, (2007)

Spin active interface self-averaging SFS, S/HM/S No sign change SFS S/HM/S only odd-frequency pairs

Odd-frequency pairs

SFS S/HM/S only even-odd mixpure odd Quasiparticle DOS in Half Metal Zero Energy Peak can be detected by tunneling spectroscopy

Summary (1)Ubiquitous presence of the odd-frequency pairs in inhomogeneous systems. (2)Low energy Andreev bound states can be expressed in terms of odd-frequency pairing (proximity effect and vortices). (3)The origin of the anomalous proximity effect in DN/spin-triplet p-wave junction is the generation of the odd-frequency pairing state. (4) Odd-frequency triplet pairs carry supercurrent in S/Half Metal/S Josephson junctions.