Reciprocal Space Magnetic Field: Physical Implications

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1 Reciprocal Space Magnetic Field: Physical Implications Junren Shi ddd Institute of Physics Chinese Academy of Sciences November 30, 2005

2 Outline Introduction Implications Conclusion 1 Introduction 2 Physical implications of the reciprocal space magnetic field Design novel transport devices Inhomogeneous phase space Effective quantum mechanics 3 Conclusion

3 Effective dynamics of Bloch electron Motivation: For a large class of crystalline materials, the equations of motion of Bloch electrons are different: ẋ = 1 E n (k) k k Ω(k) k = ee eẋ B Ω(k) reciprocal space magnetic field. It presents in systems: breaking time-reversal symmetry: magnetic materials breaking spatial inversion symmetry: surfaces, interfaces, nanotubes Sundaram and Niu, PRB 59, 14915(1999); Marder, Condensed Matter Physics. Physical consequences?

4 Aharonov-Bohm effect γ B A ds = ( A) ds = S ϕ 1 = e A ds h γ 1 ϕ 2 = e A ds h γ 2 ϕ = ϕ 2 ϕ 1 = e A ds h S B ds φ B γ

5 Berry phase Considering a quantum system controlled by a set of parameters that are slowly varying with time: H H[λ(t)] At t 1 : ψ(t 1 ) = ψ[λ(t 1 )] At t 2 : ψ(t 2 ) exp (iϕ) ψ[λ(t 2 )] t2 λ 2 γ λ 2 ϕ = 1 Berry Phase: t 1 E[λ(t)]dt + ϕ B ϕ B = i dλ ψ(λ) λ ψ(λ) γ λ 1 λ 1

6 Berry phase and k-space magnetic field k y k 2 ψ(x) = e ik x u nk (x) k 1 γ k x Ĥ(k) = Ĥ(k)u nk = ǫ n (k)u nk ( i + k)2 2m + V (x) Berry phase: A-B phase in real space: u nk ϕ B = i u nk dk ϕ AB = e A(r) ds γ k γ u k-space magnetic field: A k (k) = i u nk nk k unk Ω(k) = k A k (k) = i k u nk k

7 Symmetry consideration unk Ω(k) = k A k (k) = i k With time-reversal symmetry: With spatial inversion symmetry: Ω(k) = Ω( k) Ω(k) = Ω( k) u nk k With both symmetry: Ω(k) = 0

8 Implication Theory of everything: Ĥ = X i [ˆp i + ea(r i )] 2 2m e + X µ [ ˆP µ Z µea(r µ)] 2 2M µ X iµ Z µe 2 r i R µ + X i<j e 2 r i r j More realistic approach Effective Hamiltonian: Ĥ = i [ˆp i + ea(r i )] 2 2m e + i<j V ee (r i r j ) + Ĥe ph + Ĥph Examples: BCS theory; Quantum Hall effect... With the k-space magnetic field:?

9 Directions for exploration Applications the presence of an extra reciprocal field provides new freedom for designing novel devices. Fundamentals concept of phase space; effective quantum mechanics Physical effects Luttinger s theorem; orbital magnetization; magnetoresistance; superconductivity...

10 Outline Introduction Implications Conclusion 1 Introduction 2 Physical implications of the reciprocal space magnetic field Design novel transport devices Inhomogeneous phase space Effective quantum mechanics 3 Conclusion

11 Anomalous Hall effect M Hall effect in ferromagnetic metal: E ρ xy = R 0 B + (4πM)R s Intrinsic contribution: ẋ = 1 E n (k) k k Ω(k) k = ee I AH e ẋ = e2 E I AH F dk (2π) dω(k) Im[ωσ xy ](10 29 sec -2 ) Re[σ xy ](Ωcm) Karplus, Luttinger (1954); Jungwirth, Niu, MacDonald (2002); Fang et al. (2003); Yao et al. (2004) hω (ev)

12 Anomalous Hall insulator σ AH = e2 F dk (2π) dω(k) For a fully occupied 2D band (band insulator): σ AH = e2 dk BZ (2π) 2 Ω z(k) d 2 kω z (k) = 2πC n BZ Quantized anomalous Hall effect: σ AH = e2 h C n Protected by the band gap, extraordinarily robust!

13 Design an anomalous Hall insulator Objective: A 2D ferromagnetic band insulator A ferromagnetic 2DEG confined in an asymmetric quantum well Patterned with non-magnetic rings arranged as a triangular lattice Electron density tunable by the gate voltage Ferromagnetic 2DEG Parameters: Strength of Rashba spin-orbit coupling; Exchange interaction between electron and magnet; Lattice constant; ring radius

14 ε k x σ AH ε Reversed magnetization ε k x σ AH ε

15 Outline Introduction Implications Conclusion 1 Introduction 2 Physical implications of the reciprocal space magnetic field Design novel transport devices Inhomogeneous phase space Effective quantum mechanics 3 Conclusion

16 Breakdown of Liouville s theorem Liouville s theorem: Ensemble density in phase space is conserved. k V = r k V (t 2 ) 1 V d V (t) dt = x ẋ + k k = 0 V (t 1 ) r With k-space magnetic field: 1 V d V (t) dt 0 V (0) V (t) = 1 + (e/ )B Ω(k) V (t 1 ) k V (t 2 ) V (t 1 ) r

17 Non-uniform phase space Phase volume of a quantum state: (2π) d Statistical Physics Phase space measure: (2π) d 1 + (e/ )B Ω(k) D(r,k) = 1 (2π) d D(r,k) = 1 (2π) d ( 1 + e B Ω(k) ) Physical quantity: Ô = drdkd(r, k)o(r, k)f(r, k) f(r,k) Distribution function

18 Physical effects Introduction Implications Conclusion Fermi sea volume: Z n e = V F +δv F δv F = e dk (2π) d 1 + e B Ω Z V F B Ω B F. S. F. S. V F V F + δv F Orbital magnetization: Z E(B) = V F +δv F M = E B = e Z 2 V F Luttinger s theorem breaks down! dk (2π) d 1 + e B Ω [ǫ 0 (k) B m(k)] fi dk (2π) d i unk k h 2µ ǫ(k) Ĥi fl u nk k Confirmed by: Thonhauser, Ceresoli, Vanderbilt, Resta, cond-mat/

19 More physical effects Density of states at Fermi surface and specific heat: dk ( ρ(µ, B) = (2π) d 1 + e )δ B Ω (ǫ(k) B m(k) µ) C e = π2 3 k2 BTρ(µ,B) Magnetoresistivity in linear B: σ xx = e 2 ρ(µ,b)υ 2 F (µ,b)τ(µ,b) υ F(µ, B) = υ0 F(µ) B [ m(k F)/ k F] 1 + (e/ )B Ω Z 1 dk = 1 + e W τ(µ,b) (2π) d B Ω kk 1 k «k k 2 µ

20 Outline Introduction Implications Conclusion 1 Introduction 2 Physical implications of the reciprocal space magnetic field Design novel transport devices Inhomogeneous phase space Effective quantum mechanics 3 Conclusion

21 Effective quantum mechanics Conventional: With k-space magnetic field: Ĥ = E n (ˆk) eφ(ˆr) Ω = 0 Pierles substitution: ˆk i r + e A(r) i ψ [ ( t = E n i + e ) ] A eφ(r) ψ ǫ µνγ Ω γ [ˆx µ, ˆx ν ] = i 1 + (e/ )B Ω [ˆk µ, ˆk ν ] = i (e/ )ǫ µνγb γ 1 + (e/ )B Ω [ˆx µ, ˆk ν ] = i δ µν + (e/ )B µ Ω ν 1 + (e/ )B Ω B = 0 : ˆr i k + A k(k) General case: Quantum mechanics in non-commutative geometry

22 Many-body Hamiltonian Theory of everything: Ĥ = X i [ˆp i + ea(r i )] 2 2m e + X µ [ ˆP µ Z µea(r µ)] 2 2M µ X iµ Z µe 2 r i R µ + X i<j e 2 r i r j More realistic approach: Ĥ = [ˆp i + ea(r i )] 2 2m + V ee (r i r j ) + Ĥe ph + Ĥph i e i<j With the k-space magnetic field: Ĥ = i 2ˆk2 i 2m e + i<j V ee (ˆr i ˆr j ) + Ĥe ph(ˆr) + Ĥph [ˆr µ i, ˆrν i ] 0

23 Superconductivity Boson exchange mechanism Theory of superconductivity: Electrons develop attractive interaction through exchanging bosons (collective excitation). boson Cooper pairs e e Bosonic excitations responsible for the superconductivity: Phonon conventional BCS superconductivity Charge density wave Kohn and Luttinger, PRL, 1965 Spin fluctuation 3 He; heavy-fermion superconductors; high-t c superconductors?...

24 Ferromagnetic superconductors 60 UGe 2 30 ZrZn 2 T C UGe2 Temperature (K) Ferromagnetism Superconductivity T (K) T FM 10 T SC T (K) 10 T SC Pressure (GPa) P (kbar) Sexena et al., Nature, 2000 Pfleiderer et al., Nature, 2001 Prevailing picture: Attractive e-e interaction induced by the enhanced spin fluctuation near a quantum critical point.

25 Spin fluctuation? Introduction Implications Conclusion Puzzle: The superconducting state is only observed in the ferromagnetic phase, not in the paramagnetic phase. T Theory T Experiment PM PM FM FM SC P c SC P SC P c P Alternative theory?

26 Effective quantum mechanics Quantum mechanics in non-commutative geometry: ǫ µνγ Ω γ [ˆx µ, ˆx ν ] = i 1 + (e/ )B Ω iǫ µνγω γ [ˆk µ, ˆk ν ] = i (e/ )ǫ µνγb γ 1 + (e/ )B Ω 0 [ˆx µ, ˆk ν ] = i δ µν + (e/ )B µ Ω ν 1 + (e/ )B Ω iδ µν Zero B field limit: ˆx µ i k µ + A µ (k) Electron-electron interaction: V ee (x i x j ) V ee (ˆx i ˆx j )

27 Electron-electron interaction Classical picture Scattering between two electrons: ẋ = 1 E n (k) F ee Ω(k) k k = F ee (r r ) υ r υ θ υ r F F υ θ = F Ω Screw scattering transient pairing of electrons with finite angular momentum Superconductivity with unconventional pairing?

28 Quantum approach Second quantization V = 1 2V kk K V ee (x i x j ) υ(ˆx i ˆx j ) ˆx µ i k µ + A µ (k) u(k,k ;K)c K 2 +k c K 2 k c K 2 kc K 2 +k, u(k,k ;K) = υ(k k)e iγ( K 2 +k, K 2 +k)+iγ( K 2 k, K 2 k) Aharanov-Bohm phase under the k-space magnetic field k y Ω γ k γ(k,k ) = k k A(k) dk k k x

29 Application to a simple ferromagnetic metal Model: An isotropic two-dimensional ferromagnetic metal with a constant topological field Ω z (k) = Ω 0 Bare electron-electron interaction: υ(r) = V 0 exp[ κ TF ( r 2 + a 2 a)] (r/a) Berry phase: γ(k,k ) = 1 2 Ω 0kk sin θ Effective e-e interaction: u(k,k ;K = 0) = υ( k k )exp [ iω 0 kk sin θ ] = m u m (k,k )e imθ

30 Effective electron-electron interaction For channel m: κ u κ TF / 1 + κ TF a, φ Ω Ω 0 κ 2 u ( ) I kk u m (k,k m 1 φ κ 2 ) 2 u Ω, φ Ω 1 ( ) ( 1) m J kk m sgn(φ κ 2 Ω ) φ 2Ω 1, φ Ω > 1 u Attractive interaction: Ω 0 κ 2 u > 1 m is odd The angular momentum is υparallel to the Ω-field. More realistic model: u m (k,k)/υ (a) m= m=0 0.0 m=3 m= (k/κ 5.0 B ) 2 Ω(k) = Ω 0κ 2 B (k 2 + κ 2 B )2

31 Superconductivity Introduction Implications Conclusion (k) = 1 u(k,k ) tanh 2 E(k ) k βe(k ) 2 (k ) Pairing is determined by the most attractive m-channel. 6 5 (k) k x + ik y kt/ε B (10-3 ) p-wave Superconductor Normal Metal ε F /ε B F (0)/1.76ε B F (0) kt c 1.76 F (0) (ǫ F +ǫ B ) [ ] 1 exp ρ F u(ǫ F,ǫ F )

32 Conclusion Reciprocal space magnetic field: Design novel transport devices anomalous Hall insulator Inhomogeneous phase space Breakdown of Luttinger theorem; Fermi-surface related phenomena; orbital magnetization... Quantum mechanics in non-commutative geometry Unconventional superconductivity in ferromagnetic metals... Collaborators: Q. Niu and D. Xiao (UT-Austin) Publication: Phys. Rev. Lett. 95, (2005); More is coming

33 Conclusion Reciprocal space magnetic field: Design novel transport devices anomalous Hall insulator Inhomogeneous phase space Breakdown of Luttinger theorem; Fermi-surface related phenomena; orbital magnetization... Quantum mechanics in non-commutative geometry Unconventional superconductivity in ferromagnetic metals... Collaborators: Q. Niu and D. Xiao (UT-Austin) Publication: Phys. Rev. Lett. 95, (2005); More is coming Thank You For Your Attention!

Berry Phase Effects on Charge and Spin Transport

Berry Phase Effects on Charge and Spin Transport Qian Niu 牛谦 University of Texas at Austin 北京大学 Collaborators: Shengyuan Yang, C.P. Chuu, D. Xiao, W. Yao, D. Culcer, J.R.Shi, Y.G. Yao, G. Sundaram, M.C.