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Topological InsulatorsA new state of matter with three dimensional
topological electronic order
Topological Insulators
topological electronic order
Surface States (Topological Order in 3D)“Search & Discovery”: PHYSICS TODAY 2009 (April)
REVIEWS
L. Andrew WrayLawrence Berkeley National LabPrinceton University REVIEWS
------------------------------------------------
MZH & C.L. Kane, Rev. of Mod. Phys. 82, 3045 (2010)
MZH & J.E. Moore, Ann. Rev. of Cond-Mat. Phys. (2011)
X.L. Qi & S.C.Zhang, RMP (in press) 2011
Princeton University
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History of Z2 Topological Insulators
2005: Theoretical prediction of the Z2 TI phase (C.L. Kane and
E.J. Mele PRL 2005)
2005: Theoretical prediction of the Z2 TI phase (C.L. Kane and
E.J. Mele PRL 2005)
2005: Theoretical prediction of the Z2 TI phase (C.L. Kane and
E.J. Mele PRL 2005)
History of Z2 Topological Insulators
E.J. Mele PRL 2005)
2006-2007: Achievement of a 2D TI phase in HgTe (B.A.
Bernevig, T.L. Hughes, S.-C. Zhang, SCIENCE 2006, M. König et
al. SCIENCE 2007)
E.J. Mele PRL 2005)
2006-2007: Achievement of a 2D TI phase in HgTe (B.A.
Bernevig, T.L. Hughes, S.-C. Zhang, SCIENCE 2006, M. König et
al. SCIENCE 2007)
E.J. Mele PRL 2005)
2006-2007: Achievement of a 2D TI phase in HgTe (B.A.
Bernevig, T.L. Hughes, S.-C. Zhang, SCIENCE 2006, M. König et
al. SCIENCE 2007)al. SCIENCE 2007)
2007-2009: First discovery of a 3D TI (Bi1-xSbx alloy, L. Fu et al.
PRL 2007, D. Hsieh et al. NATURE 2008, SCIENCE 2009)
al. SCIENCE 2007)
2007-2009: First discovery of a 3D TI (Bi1-xSbx alloy, L. Fu et al.
PRL 2007, D. Hsieh et al. NATURE 2008, SCIENCE 2009)
al. SCIENCE 2007)
2007-2009: First discovery of a 3D TI (Bi1-xSbx alloy, L. Fu et al.
PRL 2007, D. Hsieh et al. NATURE 2008, SCIENCE 2009)
2008: Discovery of the M2X3 TI class (Y. Xia, arXiv 2008, H.-J.
Zhang et al. NATURE 2009, D. Hsieh et al. NATURE 2009)
2008: Discovery of the M2X3 TI class (Y. Xia, arXiv 2008, H.-J.
Zhang et al. NATURE 2009, D. Hsieh et al. NATURE 2009)
2008: Discovery of the M2X3 TI class (Y. Xia, arXiv 2008, H.-J.
Zhang et al. NATURE 2009, D. Hsieh et al. NATURE 2009)
2010: Symmetry breaking: Observation of unconventional
superconductivity in CuxBi2Se3 , magnetism in MnxBi2-xTe3
(Wray et al. Nat. Phys. 2010, Hor et al. PRB 2010)
2010: Symmetry breaking: Observation of unconventional
superconductivity in CuxBi2Se3 , magnetism in MnxBi2-xTe3
(Wray et al. Nat. Phys. 2010, Hor et al. PRB 2010)
2010-2011: Many new ternary TIs, building of TI interfaces and
nanodevices
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Lecture Outline:Lecture Outline:
1. “Experimentally discovering” topological insulators2. Understanding topological order2. Understanding topological order3. New material properties, new possibilities4. Discussion
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Bismuth Selenide
e- doped as Cu0.12Bi2Se3
Y. Xia, arXiv 2008, D. Hsieh et al. NATURE 2009, L.A. Wray et al. Nat. Phys. 2010
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Helical Dirac fermionsOne to One Spin-Linear Momentum LockingOne to One Spin-Linear Momentum Locking
+K
-K
-K +K-K
Hsieh et.al., SCIENCE 09, NATURE 09
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STM (Roushan et.al.) Spin-ARPES (Hsieh et.al.)
Spin-texture ���� Absence of Backscattering
Xu, Moore et. (06)
Spin-Independent
Spin-Dependent
Roushan et.al.,NATURE 09
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Photoemission on a TIPhotoemission on a TI
Wray PRB 2011
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Macroscopic Effects
L
Conductivity by wire size:
σB ~ A/L
σ ~ r/LσS ~ r/L
A=πr2
Critical crystal size for σB~σS in Bi2Te2Se is ~1X1X0.1mm!!
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More than just a surface state
Disallowed band structure!Typical Rashba surface state
For visual clarity, 3D parity symmetry has been broken so that each
band is singly degenerate away from the Kramers points
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Tying a knot
Note: this does not closely approximate a real band structure
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How to see the topological connection: band bending
En
erg
y (
eV
)E
ne
rgy
(
tight binding model
Momentum (A-1)
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Band bending creates new topological surface states!
Wray et al., Nat. Phys. 2010, arXiv 2011
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Partner exchange and symmetry inversionE
ne
rgy
(e
V)
En
erg
y (
Non-TI “gap”
Wray, Nature Physics 2010
Wray, arXiv:1105.4794 2011
Momentum (A-1)
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+ +
Weak TI Strong TI
+
+
+
+
+
+kZ=π
k =0
kX=π
+kZ=0
-
-
--
-
-eV
)
--
+ +
kZ=πk =π
En
erg
y (
eV
+
+ + +kZ=π
kZ=0
kX=π
- -
-
- -
-
--
-
Momentum
L. Fu, PRL 2007
Momentum
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Inducing the topological statelattice strain and spin orbit couplinglattice strain and spin orbit coupling
Xu et al., Science 2011
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Topological Invariants Define Surface States
Fully gapped
Bi2Se3 � Bi2Se3
“interface”“interface”
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Topological Insulator Quantum Hall Effect{ν
ο} (Chern Parity invariants) Z2
ν (Chern Number): Thouless et.al.,
3D Topological Insulators
Protected Protected SSurface urface SStatestates = New 2DEG= New 2DEG
XXX
Nature 08 (subm. 2007)
2D Topological InsulatorsScience 07 (subm. 2007)
Chiral Edge States (1D) Edge States (1D) by TRS
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Topological Insulator in 2D: Quantum Hall StateThouless et.al, (‘82), (Berry Phase ‘84)
Hall conductance:
σxy = ne2/h
nh/e2
σxy = ne2/h
n = Chern no. ( Edge states)n = Chern no. ( Edge states)
Chern : Quantum version (Hilbert space)
of Gauss-Bonnet formula
21( ) ( )
2 BZ
n d u uiπ
= ⋅ ∇ × ∇∫ k kk k k
Topological Property
of Gauss-Bonnet formula
n
2 BZiπ ∫ k k
Electron-occupied Bulk bands
TKNN invariant:
Topological Quantum Number
Finite n� topologically “protected” edge-states
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time-reversal invariant!
Quantum Hall Effect (insulator) : 2D Topological insulator w/ LL
Haldane model (QAH) : 2D Topological insulator w/o LL
time-reversal invariant!
1 invariant � QSHE
+
Quantum spin Hall effect 2e2/h1 invariant � QSHE Quantum spin Hall effect Kane & Mele (05a), Kane & Mele (05b) [σspinHall Not quantized]
Bernevig, Hughes, Zhang (06), Sheng, Haldane et.al., (06)
2e2/h
4
Bernevig, Hughes, Zhang (06), Sheng, Haldane et.al., (06)
Expt: Molenkamp group HgCdTe-QWells, Science (2007)
4 Invariants ���� 3D TI
Distinct Topological state in 3D Topo InsulatorMoore & Balents(07), Fu & Kane(07), Fu, Kane &Mele(07), Roy (2009)Moore & Balents(07), Fu & Kane(07), Fu, Kane &Mele(07), Roy (2009)
Expt: MZH group Bi-based Semiconductors, KITP Proc.(2007)
Nature 2008 [Submitted in 2007]
Superconductors and Magnets (Tc)3D TIs -> Superconductors and Magnets (Tc)
Many others afterwards, ~ 800 papers on arXiv
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σ = ne2/h
TransportQHE phases
σxy = ne2/h
Topological quantum numberTopological quantum number
How to experimentally “measure” the Topo Insulators
How to experimentally “measure” the
topological quantum numbers (νi) ?
4 TQNs � 16 distinct insulators
Topo Insulators
ννννο ο ο ο = Θ/π = Θ/π = Θ/π = Θ/π Θ=Θ=Θ=Θ=ππππ ((((odd)
?
No quantized transport
{{{{νννν}}}}
4 TQNs � 16 distinct insulatorsΘ=Θ=Θ=Θ=ππππ ((((odd)
Θ=Θ=Θ=Θ=2π2π2π2π (even)
Topological “Order Parameters”
{ν{ν{ν{ν0, ν, ν, ν, ν1 νννν2 νννν3 }}}}
Spin-sensitive
Momentum-resolved?
via : {{{{ννννi}}}}Momentum-resolved
Edge vs. BulkTopological quantum number
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So what can they do?So what can they do?
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Magnetoelectric EffectsMagnetoelectric Effects(not “Electromagnetic”)
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Spin helical states meeting defectsSpin helical states meeting defects
Biswas PRB 2010; arXiv 2010
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Local Magnetic Monopoles
Dyons
X.-L. Qi, Science 2009Magnetic order creates effective “axions”
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Possibilities for Surface Magnetism
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CuxBi2Se3 (Tc ~ 3.8K) : Hor et.al., PRL 2010
A Majorana PlatformCuxBi2Se3
A Majorana Platform
Topological Surface States:
Superconductivity in doped topological insulatorsSuperconductivity in doped topological insulatorsWray et.al., Nature Physics (2010)
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Majorana FermionsMajorana Fermions
Fu, PRL 2008; Wray, Nature Physics 2010; PRB 2011Non-Abelian Statistics
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Topological Superconductor (TSC)?Kitaev/Ludwig D3 class of TSC (proposed by Fu & Berg 09)
m/µµµµ from ARPES
If ODD parity � TSC
[ analog of SF He-3(B) ]
ARPES Expts
[ analog of SF He-3(B) ]
Wray et.al., Nature Physics (2010)
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Slide from J. Moore
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Topological insulators are:
Simple•Exact non-interacting models (DFT, k.p)
Topological insulators are:
•Exact non-interacting models (DFT, k.p)
•Most complexity reduces to 1D (much nicer than cuprates!!!)
•Surface is robust against non-magnetic scattering
Complicated•Theory is difficult to learn, and few people know it•Theory is difficult to learn, and few people know it
•Many surface instabilities, particularly because they occupy the same orbitals as bulk
•Lots of new phases and new physics to explore (Majorana Fermions, Dyons, magnetoelectric
effect, unusual surface transport, unusual interface physics)
•Lots of different compounds! (Tl chalcogenides, Heuslers, M2X3, etc)
•Many “simple” issues are actually complicated:
-2nd order backscattering is allowed from Anderson impurities
-Self energy is poorly understood-Self energy is poorly understood