Interacting topological insulators out of equilibrium Dimitrie Culcer D. Culcer, PRB 84, (2011) D. Culcer, Physica E 44, 860 (2012) – review on TI transport
Outline Introduction to topological insulators Transport in non-interacting topological insulators Liouville equation kinetic equation Current-induced spin polarization Electron-electron interactions Mean-field picture Interactions in TI transport Effect on conductivity and spin polarization Bilayer graphene Outlook D. Culcer, Physica E 44, 860 (2012) – review on TI transport D. Culcer, PRB 84, (2011) D. Culcer, E. H. Hwang, T. D. Stanescu, S. Das Sarma, PRB 82, (2010)
What is a topological insulator? A fancy name for a schizophrenic material Topological insulators ~ spin-orbit coupling and time reversal 2D topological insulators Insulating surface Conducting edges – chiral edge states with definite spin orientation Quantum spin-Hall effect – observed in HgTe quantum well (Koenig 2007) 3D topological insulators Insulating bulk Conducting surfaces – chiral surface states with definite spin orientation All the materials in this talk are 3D The physics discussed is 2D surface physics
What is a topological insulator? Many kinds of insulators Band insulator – energy gap >> room temperature Anderson insulator – large disorder concentration Mott insulator – strong electron-electron interactions Kondo insulator – localized electrons hybridize with conduction electrons – gap All of these can be topological insulators if spin-orbit strong enough All of the insulators above have surface states which may be topological When we say topological insulators ~ band insulators Otherwise specify e.g. topological Kondo insulators Also topological superconductors Quasiparticles – Cooper pairs All the materials in this talk are band insulators
What is a topological insulator? The first topological insulator was the quantum Hall effect (QHE) QHE is a 2D topological insulator No bulk conduction (except at special points), only edge states Edge states travel in one direction only They cannot back-scatter – have to go across the sample Hall conductivity σ xy = n (e 2 /h) n is a topological invariant – Chern number (related to Berry curvature) n counts the number of Landau levels ~ like the filling factor QHE breaks time-reversal because of the magnetic field The current generation of TIs is time-reversal invariant C.L. Kane & E.J. Mele, Physical Review Letters 95 (2005) M.Z. Hasan & C.L. Kane, Reviews of Modern Physics 82 (2010) X.-L. Qi & S.-C. Zhang, Reviews of Modern Physics 83 (2011) X.-L. Qi, T.L. Hughes & S.-C. Zhang, Physical Review B 78 (2008)
Why are some materials TI? Surface states determined by the bulk Hamiltonian Think of an ordinary band insulator Conduction band, valence band separated by a gap No spin-orbit – surface states are boring (for us) Suppose spin-orbit is now strong Think of tight-binding picture Band inversion [see Zhang et al, NP5, 438 (2009)] Mixes conduction, valence bands in bulk Surface states now connect conduction, valence bands Effective Hamiltonian on next slide Bulk conduction Bulk valence EgEg Boring semiconductor
Why are some materials TI? This is all k.p theory Set k x = k y = 0 Solve for bound states in the z-direction: k z = -i d/dz Next consider k x, k y near band edge Surface state dispersion – Dirac cone (actually Rashba) Chiral surface states, definite spin orientation TI are a one-particle phenomenon Bulk conduction Bulk valence Surface states Zhang et al, Nature Physics 5, 438 (2009)
How do we identify a TI? In TI we cannot talk about the Chern number Kane & Mele found another topological invariant – Z2 invariant Z2 invariant related to the matrix elements of the time-reversal operator Sandwich time reversal operator between all pairs of bands in the crystal Need the whole band structure – difficult calculation Z2 invariant counts the number of surface states 0 or even is trivial 1 or odd is non-trivial – odd number of Dirac cones Theorem says fermions come in pairs – pair on other surface In practice in a TI slab all surfaces have TI states This can be a problem when looking at e.g. Hall transport
What is topological protection? Topological protection really comes from time reversal. So it really is a schizophrenic insulator Disorder Like a deformation of the Hilbert space Non-magnetic disorder – TI surface states survive Electron-electron interactions Coulomb interaction does not break time reversal, so TI surface states survive Protection against weak localization and Anderson localization No backscattering (we will see later what this means) The states can be in the gap or buried in conduction/valence band The exact location of the states is not topologically protected
Most common TI - Bi 2 Se 3 Zhang et al, Nature Physics 5, 438 (2009)
More on Bi 2 Se 3 Quintuple layers 5 atoms per unit cell – ever so slightly non-Bravais Energy gap ~ 0.3 eV TI states along (111) direction High bulk dielectric constant ~ 100 Similar material Bi 2 Te 3 Has warping term in dispersion – Fermi surface not circle but hexagon Bulk dielectric constant ~ 200 Surface states close to valence band, may be obscured The exact location of the surface states is not topologically protected Surface states exist – demonstrated using STM and ARPES
Current experimental status STM enables studies of quasiparticle scattering Scattering off surface defects – initial state interferes with final state Standing-wave interference pattern Spatial modulation determined by momentum transfer during scattering Oscillations of the local DOS in real space Zhang et al, PRL 103, (2009)
Current experimental status ARPES Also measures local DOS Map Fermi surface Map dispersion relation Fermi surface maps measured using ARPES and STM agree Spin-resolved ARPES Measures the spin polarization of emitted electrons – Hsieh et al, Science 323, 919 (2009). Alpichshev et al, PRL 104, (2010)
Current experimental status Unintentional Se vacancies – residual doping Fermi level in conduction band – most TI’s are bad metals Surface states not clearly seen in transport – obscured by bulk conduction Seen Landau levels but no quantum Hall effect Experimental problems Ca compensates n-doping but introduces disorder – impurity band Low mobilities, typically < 1000 cm 2 /Vs Atmosphere provides n-doping TI surfaces remain poorly understood experimentally All of these aspects discussed in review D. Culcer, Physica E 44, 860 (2011)
Interactions + chirality - nontrivial Exotic phases with correlations cf. talk by Kou Su-Peng this morning 流光溢彩 See also Greg Fiete, Physica E 44, 844 (2012) review on spin liquid in TI + ee
TI Hamiltonian – no interactions H = H 0 + H E + U H 0 = band H E = Electric field U = Scattering potential Impurity average ε F τ p >> 1 τ p = momentum relaxation time ε F in bulk gap – electrons T=0 no phonons, no ee-scattering Bulk conduction Bulk valence Surface states εFεF
TI vs. Familiar Materials Unlike graphene σ is pseudospin No valleys Unlike semiconductors SO is weak in semiconductors No spin precession in TI Semiconductor with SO
Effective magnetic field kx kx k y Spin-momentum locking Equilibrium picture General picture at each k Out of equilibrium the spin may deviate slightly from the direction of the effective magnetic field Effective magnetic field Spin
Liouville equation Apply electric field ~ study density matrix Starting point: Liouville equation Method of solution – Nakajima-Zwanzig projection ( 中岛二十 ) Project onto k and s kinetic equation Divide into equations for diagonal and off-diagonal parts
Kinetic equation Reduce to equation for f – like Boltzmann equation Scattering term This is 1 st Born approximation – Fermi Golden Rule Spin precession Scattering Driving term due to the electric field Scattering inScattering out
Scattering term Density matrix = Scalar + Spin Spin Scattering term – in equilibrium only conserved spin Suppression of backscattering Conserved spinNon-conserved spin Effective magnetic field Spin
Kinetic equation Conserved spin density Precessing spin density Solution – expansion in 1/(Ak F τ) Ak F τ ~ (Fermi energy) x (momentum scattering time) Assumes (Ak F τ) >> 1 – in this sense it is semiclassical Conserved spin gives leading order term linear inτ Precessing spin gives next-to-leading term independent ofτ Culcer, Hwang, Stanescu, Das Sarma, PRB 82, (2010)
Conductivity Conserved spin ~ like Drude conductivity Precessing spin ~ extra contribution Needs some care Produces a singular contribution to the conductivity Cf. graphene Zitterbewegung and minimum conductivity Momentum relaxation time ζ contains the angular dependence of the scattering potential. W is the strength of the scattering potential.
Topological protection Protection exists only against backscattering – π Can scatter through any other angle – π/2 dominates transport Transport theory results similar to graphene Conventional picture of transport applies Electric field drives carriers, impurities balance driving force There is nothing in TI transport that makes it special States robust against non-magnetic disorder Disorder will not destroy TI behavior But transport still involves scattering, dissipation Remember transport is irreversible Careful with metallic contacts – not localized May destroy TI behavior if too big
Spin-polarized current Current operator proportional to spin No equivalent in graphene Charge current = spin polarization spins/unit cell area Spin polarization exists throughout surface Not in bulk because Bi 2 Se 3 has inversion symmetry This is a signature of surface transport Smoking gun for TI behavior? Detection – Faraday/Kerr effects Insulating bulk Conducting edge
Spin-polarized current E // x No E kx kx kx kx k y
Electron-electron interactions TI is a single-particle phenomenon Recall topological protection – transport irreversible TI phenomenology – robust against disorder and ee-interactions But this applies to the equilibrium situation Out-of-plane magnetic field – out-of-plane spin polarization (Zeeman) In-plane magnetic field does NOTHING In-plane electric field – in-plane spin polarization (similar to Zeeman) Because of spin-orbit How do electron-electron interactions affect the spin polarization? Can interactions destroy the TI phase out of equilibrium? D. Culcer, PRB 84, (2011)
Exchange enhancement Exchange enhancement (standard Fermi liquid theory) Take a metal and apply a magnetic field – Zeeman interaction ee-interactions enhance the response to the magnetic field Enhancement depends on EXCHANGE and DENSITY OF STATES Stoner criterion If Exchange x Density of States large enough … This favors magnetic order Electric field + SO = magnetic field Can interactions destroy TI according to some Stoner criterion? D. Culcer, PRB 84, (2011) MajorityMinority EFEF DOS
Interacting TI The Hamiltonian has a single-particle part and an interaction part Matrix elements Matrix elements in the basis of plane waves D. Culcer, PRB 84, (2011) This is just the band Hamiltonian – Dirac This is the Coulomb interaction term This is just the electron-electron Coulomb potential Plane wave states
Screening Quasi-2D screening, up to 2k F the dielectric function is (RPA) Effective scattering potential All potentials renormalized – ee, impurities (below) Quasi-2D, screened Coulomb potentials remain long-range r s measures ratio of Coulomb interaction to kinetic energy In TI it is a constant (same as fine structure constant) Culcer, Hwang, Stanescu, Das Sarma, PRB 82, (2010)
Electron-electron interactions Screening – RPA ee-Coulomb potential also screened Mean-field Hartree-Fock calculation Analogous to Keldysh – real part of ee self energy (reactive) Interactions appear in two places: screening and Hartree-Fock mean field No ee collisions (i.e. no extra scattering term = no ee dissipative term) This is NOT Coulomb drag D. Culcer, PRB 84, (2011)
Mean field Kinetic equation – reduce to one-particle using Wick’s theorem Interactions give a mean-field correction B MF Think of it as an exchange term B MF – effective k-dependent ee-Hamiltonian Spin polarization generates new spin polarization – self-consistent Renormalization (B MF goes into driving term) D. Culcer, PRB 84, (2011)
Electron-electron interactions Renormalization of spin density due to interactions Correction to density matrix called S ee Comes from precessing term – i.e. rotation This is the bare correction How can spin rotation give a renormalization of the spin density? Remember the current operator is proportional to the spin Whenever we say charge current we also mean spin polarization Whenever we say spin polarization we also mean charge current D. Culcer, PRB 84, (2011)
What happens? Spin-momentum locking Effective SO field wants to align the spin with itself Many-body correlations – think of it as EXCHANGE Exchange wants to align the spin against existing polarization Exchange tilts the electron spin away from the effective SO field If no spin polarization exchange does nothing D. Culcer, PRB 84, (2011) This is why the net effect is a rotation It shows up in the perpendicular part of density matrix because it is a rotation
Enhancement and precession kx kx k y kx kx Non-interacting Interacting
Electron-electron interactions First-order correction Same form as the non-interacting case, same density dependence Because of linear screening – k TF k F Not observable by itself Embedded as it were in original result Kinetic equation solved analytically to all orders in r s D. Culcer, PRB 84, (2011)
Reduction of the conductivity D. Culcer, PRB 84, (2011)
Why reduction? Interactions lower Fermi velocity They enhance the density of states Another way of looking at the problem TI have only one Fermi surface Rashba SOC, interactions enhance current-induced spin polarization D. Culcer, PRB 84, (2011) Polarization reduced. TI is like minority spin subband. Spins gain energy by lining up with the field. Minority spin subband, spins gain energy. Polarization reduced. Majority spin subband, spins save energy. Polarization enhanced. TI Rashba
Current TIs Current TIs have a large permittivity ~ hundreds Large screening r s is small (but result holds even if r s made artificially large) Coulomb potential strongly screened Interaction effects expected to be weak For example Bi 2 Se 3 Relative permittivity ~ 100 Interactions account for up to 15% of conductivity Bi 2 Te 3 has relative permittivity ~ 200 This is only the beginning – first generation TI D. Culcer, PRB 84, (2011)
Interactions out of equilibrium T = 0 conductivity of interacting system Same form as non-interacting TI But renormalized – reduction factor Reduction is density independent Peculiar feature of linear dispersion – linear screening The only thing that can be `varied’ is the permittivity No Stoner-like divergence Is TI phenomenology robust against interactions out of equilibrium? YES This is an exact result (within HF/RPA) D. Culcer, PRB 84, (2011)
Bilayer graphene Quadratic spectrum Perhaps renormalization is observable Chirality But pseudospin winds twice around FS Gapless Gap can be induced by out-of-plane electric field As Dirac point is approached Competing ground states See work by A. H. MacDonald, V. Fal’ko, L. Levitov Wei-Zhe Liu, A. H. MacDonald, and D. Culcer (2012) εFεF
Bilayer graphene Screening – RPA Conductivity renormalization Wei-Zhe Liu, A. H. MacDonald, and D. Culcer (2012)
Bilayer graphene BLG and TI interactions in transport Interestingly: 大同小异 WHY? Gain a factor of k in the pseudospin density Lose a factor of k in screening Overall result Small renormalization of conductivity Weak density dependence Wei-Zhe Liu, A. H. MacDonald, and D. Culcer (2012)
Bilayer graphene Fractional change
Outlook TI thin films with tunneling between layers Mass term but does not break time reversal – see work by S. Q. Shen Exotic phases – e.g. QAH state at Dirac point What do Friedel oscillations look like? Interactions in non-equilibrium TI – other aspects Kondo resistance minimum So far few theories of the Kondo effect in TI Expect difference between small SO and large SO D. Culcer, PRB 84, (2011) D. Culcer, Physica E 44, 860 (2012) – review on TI transport Wei-Zhe Liu, A. H. MacDonald, and D. Culcer (2012)