Integer quantum Hall effect for bosons: A physical realization
T. Senthil (MIT) and Michael Levin (UMCP). (arXiv:1206.1604)
Thanks: Xie Chen, Zhengchen Liu, Zhengcheng Gu, Xiao-gang Wen, and Ashvin Vishwanath.
Saturday, July 20, 2013
An obsession in modern condensed matter physics
``Exotic” Phases of Matter
- Gapped phases with ``topological quantum order”, fractional quantum numbers(eg, fractional quantum Hall state, gapped quantum spin liquids)
- phases with gapless excitations not required by symmetry alone(eg, fermi and non-fermi liquid metals, gapless quantum spin liquids)
Emergent non-local structure in ground state wavefunction:
Characterize as ``long range quantum entanglement”
Saturday, July 20, 2013
How ``simple” can ``interesting” be?
Long range entangled phases have many interesting properties.
Some of these interesting things may not actually require the long range entanglement.
A sub-obsession: how exotic can a phase with short ranged entanglement be?
Dramatic progress in the context of topological band structures of free fermion models in recent years.
Saturday, July 20, 2013
Integer quantum Hall effect of electrons: the original topological insulator
Saturday, July 20, 2013
Modern topological insulators
Key characterization: Non-trivial surface states with gapless excitations protected by some symmetry
Saturday, July 20, 2013
Interactions?
Current frontier: interaction dominated generalizations of the concept of topological insulators?
Move away from the crutch of free fermion Hamiltonians.
Useful first step: study possibility of topological insulators of bosons
Necessitates thinking more generally about these phases without the aid of a free fermion model.
Saturday, July 20, 2013
Integer Quantum Hall Effect (IQHE) for bosons?
Integer quantum Hall effect of fermions: Often understand in terms of filling a full Landau level.
For bosons this obviously fails (no Pauli).
Can bosons be in an IQHE state with (1) a quantized integer Hall conductivity(2) no fractionalized excitations or topological order (unique ground state on closed manifolds)(3) a bulk gap
Yes! (according to recent progress in general classification of short ranged entangled phases)1. Cohomology classification (Chen, Liu, Gu, Wen, 2011)2. ?? (Kitaev, unpublished)3. Chern-Simons classification (Lu, Vishwanath, 2012)
Saturday, July 20, 2013
This talk
A physical realization of an integer quantum Hall state of bosons
Simple, possibly experimentally relevant, example of the kind of state the formal classification shows is allowed to exist.
Saturday, July 20, 2013
Two component bosons in a strong magnetic field
H =�
I
HI +Hint (1)
HI =
�d2xb
†I
−
��∇− i �A
�2
2m− µ
bI (2)
Hint =
�d2xd
2x�ρI(x)VIJ(x− x
�)ρJ(x�) (3)
Two boson species bI each at filling factor ν = 1
External magnetic field �B = �∇× �A.ρI(x) = b†I(x)bI(x) = density of species I
Saturday, July 20, 2013
Symmetries and picture
Number of bosons N1, N2 of each species separately conserved: two separateglobal U(1) symmetries.
B-field
Species 1
Species 2
Total charge = N1+N2
Call N1 - N2 = total ``pseudospin”
Charge current
Pseudospin current
Later relax to just conservation of total boson number
Saturday, July 20, 2013
Guess for a possible ground state
If interspecies repulsion V12 comparable or bigger than same species repulsionV11, V22, particles of opposite species will try to avoid each other.
Guess that first quantized ground state wavefunction has structure
ψ = “.......�
i.j
(zi − wj)”e−
�i
|zi|2+|wi|
2
4l2B (1)
zi, wi: complex coordinates of the two boson species.
Saturday, July 20, 2013
Flux attachment mean field theory �
i.j(zi − wj): particle of each species sees particle of the other species as avortex.
Flux attachment theory:
Attach one flux quantum of one species to each boson of other species.“Mutual composite bosons”
1 2
ν = 1 => on average attached flux cancels external magnetic flux.Mutual composite bosons move in zero average field.
Saturday, July 20, 2013
Chern-Simons Landau Ginzburg theory
Reformulate in terms of mutual composite bosons. Implement flux attachment through Chern-Simons gauge fields.
L =�
I
LI + Lint + LCS
LI = b̃∗I(∂0 − iAI0 + iαI0)b̃I −|�∇b̃I − i( �AI − �αI)b̃I |2
2m
+ µ|b̃I |2
Lint = −VIJ |b̃I |2|b̃J |2
LCS =1
4π�µνλ (α1µ∂να2λ + α2µ∂να1λ) (1)
Saturday, July 20, 2013
Chern-Simons Landau Ginzburg theory
Reformulate in terms of mutual composite bosons. Implement flux attachment through Chern-Simons gauge fields.
L =�
I
LI + Lint + LCS
LI = b̃∗I(∂0 − iAI0 + iαI0)b̃I −|�∇b̃I − i( �AI − �αI)b̃I |2
2m
+ µ|b̃I |2
Lint = −VIJ |b̃I |2|b̃J |2
LCS =1
4π�µνλ (α1µ∂να2λ + α2µ∂να1λ) (1)
Mutual Chern-Simons implements flux attachment
Chern-Simons gauge fields
Saturday, July 20, 2013
Chern-Simons Landau Ginzburg theory
Reformulate in terms of mutual composite bosons. Implement flux attachment through Chern-Simons gauge fields.
L =�
I
LI + Lint + LCS
LI = b̃∗I(∂0 − iAI0 + iαI0)b̃I −|�∇b̃I − i( �AI − �αI)b̃I |2
2m
+ µ|b̃I |2
Lint = −VIJ |b̃I |2|b̃J |2
LCS =1
4π�µνλ (α1µ∂να2λ + α2µ∂να1λ) (1)
Probe gauge fieldsMutual Chern-Simons implements flux
attachment
Chern-Simons gauge fields
Mutual composite fermions see zero average field: condense them. Internal Chern-Simons gauge fields lock to probe gauge fields.
Saturday, July 20, 2013
Physical properties: Hall transport
Effective probe Lagrangian
Leff =1
4π�µνλ (A1µ∂νA2λ +A2µ∂νA1λ) (1)
New probe gauge fields that couple to charge and pseudospin currents Ac =A1+A2
2 , As =A1−A2
2 .
Leff =1
2π�µνλ (Acµ∂νAcλ −Asµ∂νAsλ) (2)
Electrical Hall conductivity σxy = 2
Pseudospin Hall conductivity σsxy = −2.
“Integer quantum Hall effect”
Saturday, July 20, 2013
Edge states
Charge current Pseudospin current
Comments: 1. Counterpropagating edge states but only one branch transports charge.
2. Thermal Hall conductivity = 0
Saturday, July 20, 2013
Symmetry protection of edge states
B-field
Species 1
Species 2
Include interspecies tunneling: Pseudospin not conserved, only total particle number conserved.
Counterpropagating edge modes cannot backscatter due to charge conservation.
Edge modes are preserved so long as total charge is conserved.
``Symmetry Protected Topological Phase” of bosons
Saturday, July 20, 2013
Effective topological field theory
Two component Chern-Simons theory
L =1
4π(a1da2 + a2da1) +
1
2π(da1 + da2)Ac (1)
“K-matrix” = σx
Unique ground state on closed manifolds as |DetK| = 1
Connect to general discussion of Lu, Vishwanath (Ashvin talk)
Saturday, July 20, 2013
Ground state wavefunction(ignore interspecies tunneling)
Naive guess Ψ ({zi, wj}) =�
i,j
(zi − wj) · e−�
i|zi|
2+|wi|2
4 (1)
Problem: Unstable to phase separation (see using Laughlin plasma analogy) Fix, for example, using ideas initiated by Jain (1993) for some fermionic quantum Hall states
Ψflux = PLLL
�
i<j
|zi − zj |2 ·�
i<j
|wi − wj |2
·�
i,j
(zi − wj) · e−�
i|zi|
2+|wi|2
4 (1)
PLLL: projection to lowest Landau level
Saturday, July 20, 2013
Pseudospin properties
The edge theory for this state is identical to the SU(2)1 WZW conformal
field theory.
Edge theory has (emergent) pseudospin SU(2) rotation symmetry.
Suggests state itself can be stabilized for a pseudospin SU(2) invariant
Hamiltonian.
Can show wavefunction of previous slide is actually a pseudospin singlet
Saturday, July 20, 2013
Microscopics: a simple Hamiltonian
H =�
I
HI +Hint (1)
HI =
�d2xb
†I
−
��∇− i �A
�2
2m− µ
bI (2)
Hint =
�d2xd
2x�ρI(x)VIJ(x− x
�)ρJ(x�) (3)
Simple and realistic interaction:
VII(�x) = gsδ(2)(�x) (1)
V12(�x) = gdδ(2)(�x) (2)
gs = gd: Pseudospin SU(2) invariance
Saturday, July 20, 2013
Possible Phase diagram
gd/gs10
∞
Decoupled: Pfaffian + Pfaffian
(non-abelian)
Phase separated: Possibly non-abelian k= 4 Read-Rezayi state SU(2) symmetric point:
Near SU(2) symmetric point, recent exact diagonalization work show an incompressible, spin singlet state (Grass et al, 2012arXiv1204.5423G, Furukawa, Ueda 2012arXiv1205.2169F)
Candidates: 1. Boson IQHE 2. A non-abelian spin singlet state (Ardonne, Schoutens 1999)
Saturday, July 20, 2013
Prospects - experiments
Obvious place to look is in ultracold atoms in strong artificial magnetic fields.
The delta function repulsion is realistic and controllable.
Challenge: get fields high enough to be in the quantum Hall regime
Saturday, July 20, 2013
Prospects - future theory
Dramatic progress in classification of ``Symmetry Protected Topological” and other Short Ranged Entangled Phases.
Future: 1. Better understanding of their universal physical properties, and their physical/experimental realizations.
2. Interplay between symmetry and ``long range entanglement”.
Saturday, July 20, 2013