topological)superconductors - 東京大学 · 3 topological&table& &(1cband&scs)...
TRANSCRIPT
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Topological Superconductors
Nagoya University, Masatoshi Sato
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Theory Seminar at ISSP 2004/09/03
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Topological Table (1-‐band SCs)
homotopy top. stable node space of GS
T-‐invariant
T-‐breaking
T-‐invariant
T-‐breaking (unitary)
T-‐breaking (non-‐unitary)
Sato (04) (unpublished)
high Tc cuprate
d+id SC
3He-‐A
3He-‐B
Sr2RuO4
• Orbifold structure due to TRI (= Kramers degeneracy ) [Horava (05), Kane-‐Mele(05)]
• Altland-‐Zirnbauer classificaYon (= Disorder effects )
[Schnyder et al (08)]
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• Satoshi Fujimoto (Kyoto University)
• Yoshiro Takahashi (Kyoto University)
• Yukio Tanaka (Nagoya University) • Keiji Yada (Nagoya University) • Ai Yamakage (Nagoya University)
• Yuji Ueno (Nagoya University)
• Takeshi Mizushima (Okayama University)
• Kazushige Machida (Okayama University)
• Yasumasa Tsutsumi (Riken)
• Takuto Kawakami (NIMS)
In collabora>on with
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Review paper Y. Tanaka, MS, N. Nagaosa, “Symmetry and Topology in Superconductor” Journal of Physical Society of Japan, 81 (2012) 011013 (open access)
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Outline
Part 1. What is topological superconductor ?
1. Why topological phase is useful ? 2. Prototype of topological phase – quantum Hall state 3. Topological superconductors 4. Majorana fermions 5. Which system supports Majorana fermions
Part 2. Symmetry Protected Majorana fermions in unconven>onal SCs
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Part 1. What is topological superconductor ?
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Topological phase
② Topological # Topological phase Non-‐topological phase
-‐Bulk-‐
① Gapped system such as insulators and superconductors
③ Topological # cannot change unless the bulk gap closes 7
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Topological phase
② MathemaYcally, the existence of gapless states is ensured by the bulk topological #
-‐Boundary-‐
① The existence of gapless state on the boundary
③ We can operate the gapless state without destroying the bulk state
Bulk-‐edge correspondence
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Why topological phase is useful ?
• The bulk state is gapped, so it is stable against local perturbaYon (i.e. decoherence free)
• Nevertheless, it support gapless states on the boundary, so at the same Yme there exist manageable quantum states (i.e. qubits)
Considering these two properYes, we can expect that topological phase is an ideal plaRorm of quantum devices (i.e. topological quantum computer)
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Quantum Hall state: Prototype of topological phase
Hall conductance is quanYzed in the unit of e2/h
e: electron charge h: Planck const.
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Bulk of QH state
• QH states are gapped in the bulk due to the formaYon of Landau level.
• They have a non-‐zero topological #.
M filled bands
N empty bands
Thouless-‐Kohmoto et al. (82) Kohmoto (85)
TKNN # (or Chern #)
Bloch wave fn. of occupied state
Landau level in a crystal filed
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• The quanYzaYon of Hall conductance is explained by the quanYzaYon of topological #
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Edge of QH state
• Due to the confining potenYal, occupied Landau levels cross the Fermi energy near the edge. So there exist gapless states localized on the boundary.
• The quanYzaYon of Hall conductance is explained by the quanYzaYon of the number of edge states.
Landau level + confining potenYal
To obtain the edge, we introduce confining potenYal
Halperin (81)
Gapless states carry the Hall conductance
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νch=νedge
① Bulk
② Edge
We have two different views of Hall conductance
The number of the edge states should be the same as topological #
bulk-‐edge correspondence 14
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QH states (summary)
• QH states are gapped systems with non-‐zero topological #.
• QH states support gapless edge states.
• The gapless states are ensured by the bulk topological #.
Topological phase
The Hall current is well-‐controlled and the quanYzaYon is extremely accurate.
Ex.) Hall effect devices
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Topological Superconductors
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A close similarity between quantum Hall states and SCs
Integer quantum Hall state
Superconduc>ng state
bulk gapped (Landau level)
gapped (gap funcYon)
edge Gapless edge state Andreev bound state
We can naturally expect that topological phase is possible for superconducYng state.
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Topological superconductors Qi et al.(09) , Schnyder et al (08), MS (09), Roy (08), …
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Topologically protected state = Majorana fermion
Majorana Fermion
Dirac fermion with Majorana condiYon
1. Dirac Hamiltonian
2. Majorana condiYon
parYcle = anYparYcle
For the gapless boundary states, their Hamiltonians are naturally given by the Dirac Hamiltonians
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Why the Majorana condi>on ?
The Majorana condiYon is imposed by superconducYvity
[Wilczek , Nature (09)]
Majorana condiYon
quasiparYcle anY-‐quasiparYcle quasiparYcle in Nambu rep.
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different bulk topological # = different Majorana fermions
2+1D Yme-‐reversal breaking SC
2+1D Yme-‐reversal invariant SC
3+1D Yme-‐reversal invariant SC
1st Chern # (TKNN82, Kohmoto85)
Z2 number (Kane-‐Mele 06, Qi et al (08))
3D winding # (Schnyder et al (08))
1+1D chiral edge mode
1+1D helical edge mode
2+1D helical surface fermion
Sr2RuO4 Noncentosymmetric SC
(MS-‐Fujimto(09)) 3He B
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Which system support Majorana fermions ?
• Spin-‐triplet (odd-‐parity) superconductors
• SuperconducYng states with SO interacYon
Volovik (86), Read-‐Green(00)
MS, Physics Lerers B535,126 (03), Fu-‐Kane (08)
MS, Takahashi, Fujimoto PRL(09) PRB(10), J.Sau et al (11)
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A representa>ve example of topological SC: spinless chiral p-‐wave SC in 2+1 dimensions
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BdG Hamiltonian
with
chiral p-‐wave
spinless chiral p-‐wave SC
[Read-‐Green (00)]
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Topological number = 1st Chern number
TKNN (82), Kohmoto(85)
MS (09)
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Fermi surface
Spectrum
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SC
2 gapless edge modes (les-‐moving , right moving, on different sides on boundaries)
Edge state
Bulk-‐edge correspondence
Majorana fermion
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In the second case, there also exist a single Majorana zero mode in a vortex
We need a pair of the zero modes to define creaYon op.
vortex 1 vortex 2
non-‐Abelian anyon
topological quantum computer 25
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[Sato (09), Sato (10), Fu-‐Berg (10)]
If the number of TRIMs enclosed by the Fermi surface is odd, the spin-‐triplet SC is (strongly) topological.
2D spinless SC )
SC Even Odd
Chiral Majorana mode
For spin-‐triplet SCs ( or odd parity SCs), there exists a simple criterion for topological phases
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3D Yme-‐reversal invariant spin-‐triplet SC )
Even Odd
Majorana fermion (001) (001) BW gap fn.
With proper topology of the Fermi surface, spin-‐triplet SCs (or odd-‐parity SCs) naturally become topological.
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Recently, it has been found that s-‐wave superconductors also can support Majorana fermion.
A) MS, Physics Lerers B535 ,126 (03), Fu-‐Kane PRL (08)
B) MS-‐Takahashi-‐Fujimoto ,Phys. Rev. Ler. 103, 020401 (09) ; MS-‐Takahashi-‐Fujimoto, Phys. Rev. B82, 134521 (10) (Editor’s suggesYon), J. Sau et al, PRL (10), J. Alicea PRB (10)
Key point: Spin-‐orbit interac>on
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Majorna fermion in spin-‐singlet SC
① 2+1 dim Dirac fermion + s-‐wave Cooper pair
Zero mode in a vortex
With Majorana condiYon, non-‐Abelian anyon is realized
[Jackiw-‐Rossi (81), Callan-‐Harvey(85)]
[MS (03)]
MS, Physics Lerers B535 ,126 (03)
vortex
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On the surface of topological insulator [Fu-‐Kane (08)]
Spin-‐orbit interacYon => topological insulator
Topological insulator
S-‐wave SC
Dirac fermion + s-‐wave SC
Bi2Se3
Bi1-‐xSbx
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Hsieh et al., Nature (2008)
Nishide et al., PRB (2010)
Hsieh et al., Nature (2009)
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2. S-‐wave superconductor with Rashba SO interacYon
[MS, Takahashi, Fujimoto PRL(09) PRB(10)]
Rashba SO
p-‐wave gap is induced by Rashba SO int.
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Topological superconducYvity can be obtained if we choose a suitable Fermi surface
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Topological Edge state
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Sato-‐Takahashi-‐Fujimoto (09, 10)
superconducor
Zeeman field
Fermi Level
Two Fermi surfaces Single Fermi surface Fermi surface
Edge state
Majorana fermion
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Mourik et al., Science (2012)
InSb/ NbTiN
1D Nanowire
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Zeeman field MF
nanowire
Lutchyn et al (10), Oreg et al (10)
Majorana fermions are realized under a strong magneYc field saYsfying
MS-‐Takahashi-‐Fujimoto (09)
Majorana Fermion
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Majorana fermions are not merely a theoreYcal possibility now, but they are what we can realize somehow in experiments.
Topological superconductor is not a fancy way to rewrite the exisYng theory of the Andreev bound state, but it can be a useful way to predict novel properYes in SCs.
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Symmetry Protected MFs in Superconductors
Y. Ueno, A. Yamakage, Y. Tanaka, MS, arXiv:1303.0202
MS, A. Yamakage, T. Mizushima, arXiv:1305.7469
Chui, Yao, Ryu, arXiv: 1303.1843 Zhang, Kane, Mele, arXiv:1303.4144
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Majorana Fermions
• Majorana fermions are naturally realized in spinless SCs
Dirac fermion + s-‐wave condensate
S-‐wave superconducYng state with Rashba SO + Zeeman field
Zeeman field
Fermi Level
Non spin-‐degenerate single Fermi surface
MS(03), Fu-‐Kane (08)
MS-‐Takahashi-‐Fujimoto (09), J. Sau et al (10)
Hsieh et al
Spinless chiral p-‐wave SC Read-‐ Green (00)
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Why Majorana Fermions favor spinless SCs ?
Nira’s talk at JPSJ meeYng (12)
For spinless SCs, we have the Majorana condiYon naturally.
However, the spin degrees of freedoms obscure the Majorana condiYon
Majorana condiYon
Majorana condiYon
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Moreover, spinful SCs support MFs in pairs because of the spin degeneracy.
They can be considered as Dirac fermions as well as MFs
The Dirac fermions are easily gapped away by the Dirac mass term
No topologically stable MFs
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To avoid these difficulYes, a half-‐quantum vortex has been considered.
Twist in spin space
Only downspin sector supports a vortex
= A vortex in spinless SCs
Topologically stabbe MF
However, the twist in spin space makes the configuraYon unstable, so the experimental realizaYon is challenging.
Ivanov (01)
Chung-‐Bluhm-‐Kim(07)
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Ques>on
Is there another way to realize Majorana fermions in spinful SCs ?
Key observa>on
If there is an addiYonal symmetry such as Yme-‐reversal symmetry, Majorana fermions can be realized in spinful SCs
CuxBi2Se3 CuxBi2Se3 Fu-‐Berg (10)
Sasaki-‐Kriener-‐Segawa-‐Yada-‐Tanaka-‐MS -‐Ando(11)
Yamakage-‐-‐Yada-‐MS-‐Tanaka(12)
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Thus, they naturally can be considered as two independent parYcles, not as a single Dirac fermion.
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Ex.) 1D spinful px-‐wave superconductor
A pair of MFs
No scarering between and
Kramers theorem
Actually, the Dirac mass term is forbidden by the Yme-‐reversal symmetry.
Topologically stable MF
px-‐wave SC
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Our idea
To obtain topologically stable MFs in spinful SCs, we use symmetry specific to material structures.
c.f.) Topological crystalline insulators Sr2RuO4
UPt3
Ex.) point group symmetry
Fu (11)
D6h D4h
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In parYcular, we consider the mirror reflecYon symmetry
Now consider how the mirror reflecYon symmetry protect MFs
coordinate
spin
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2dim spinful SC
Mirror symmetry with respect to xy-‐plane
BdG Hamiltonian
Our system
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Basic idea
Using the eigen value of mirror operator, spinful SC can be separated into a pair of spinless SCs
For each spinless SCs, the mirror Chern number can be defined like topological crystalline insulators (TCI).
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However, there is an important difference between TCIs and SCs
Par>cle-‐hole symmetry = Majorana condi>on
The problem is how the parYcle-‐hole symmetry is realized in the spinless SCs.
PH symmetry
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Key point
Two different mirror symmetries are possible in SCs.
S-‐wave SC
a)
b) U(1) gauge sym
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Even
Dirac fermion
• Mirror subsector does not support its own parYcle-‐hole symmetry.
• Mirror subsector is topologically the same as quantum Hall states.
• Symmetry protected topological states are Dirac fermions.
Class A
Class A
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Odd
Majorana fermion
• Mirror subsector supports its own parYcle-‐hole symmetry . • Mirror subsector is topologically the same as spinless SCs. • Symmetry protected topological states are Majorana fermions • Majorana zero mode can exit in a vortex or in a dislocaYon
Z class D
1D 2D 3D
Z2 -‐
Class D
Class D
Schnyder et al (08) Teo-‐Kane (10)
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Mirror subsector is class A
Only Dirac fermions are possible
No PH symmetry in mirror subsector
PH symmetry in mirror subsector
Mirror subsector is class D
Majorana fermions are possible in each mirror sector
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Applica>on to Sr2RuO4
C. Bergemann
Fermi surface
Maeno, Kiraka, Nomura, Yonezawa, Ishida, JPSJ (12)
• (quasi) 2-‐dimensional Yme-‐reversal breaking spin-‐triplet SC
• InteresYngly, the NMR measurements have suggested that d-‐vector is normal to the z-‐direc>on in the presence of magneYc fields along the z-‐direcYon.
We can expect Majorana Fermions !!
Odd
HZ
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Our model All three bands and relevant SO int. are taken into account.
Fermi surface
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edge dislocation
Sr2RuO4
Topological state
Majorana fermion
edge state
Majorana zero mode
The other three mirror odd gap funcYons also show qualitaYvely the same results. 53
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Thin film of 3He-‐A MS, Yamakage, Mizushima (13)
Our arguments also work for other unconvenYonal SCs/SFs
LDOS at core of integer vortex
3He-‐A
Majorana zero modes exist in integer vortex when
vortex
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These symmetry protected MFs show non-‐trivial phenomena like usual MF if the mirror symmetry is preserved.
Vortex
Due to the existence of MF, a vortex in each mirror subsector obeys non-‐Abelian staYsiYcs . Therefore, a vortex in original spinful SC also obeys non-‐Abelian sta>s>cs
Remark
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Summary
1. We have revealed the condiYon necessary to obtain Majorana fermions protected by the mirror symmetry.
2. With the mirror symmetry, unconvenYnal spinful SCs can host Majorana fermions
In parYcular, Sr2RuO4 can hosts Majorana zero mode in a vortex and a dislocaYon without considering half-‐quantum vortex
3. Our arguments are general and applicable to 3 dimensional spinful SCs.
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