controlling one- and two photon transports in one-dimension
TRANSCRIPT
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ChangChang--PuPu
SunSun
Institute of Theoretical Physics Chinese Academy of Sciences
Controlling oneControlling one--
and two photon transports and two photon transports in onein one--dimensiondimension
Sept.,2010Sept.,2010
http://www.itp.ac.cn/~suncp
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Outline
1. L. Zhou, Z. R. Gong, Y.X., Liu,
CPS
, F. Nori,
Phys. Rev. Lett
101, 100501 (2008)
2. T. Shi, CPS, Phys. Rev. B 79, 205111 (2009) 3. T. Shi, S.H. Fan, CPS, arXiv:1009.2828
•
Background and motivations•
Single photon transport with a controller
•
Two photon transport in waveguide •
Towards active manipulation for photons
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Relevant papers
1. Controlling Quasibound States in 1D Continuum Through Electromagnetic Induced Transparency Mechanism Z. R. Gong, H. Ian, Lan Zhou, CPS, Phys. Rev. A 78, 053806 (2008)
2. Intrinsic Cavity QED and Emergent Quasi-Normal Modes for Single Photon H. Dong, Z. R. Gong, H. Ian, L. Zhou, CPS, Phys. Rev. A 79, 063847(2009)
3. Quantum super-cavity with atomic mirrors Lan Zhou, H. Dong, Yu-xi Liu, CPS, F.Nori. Phys. Rev. A 78, 063827 (2008)
4. Lehmann-Symanzik-Zimmermann Reduction Approach to Multi-Photon Scattering in Coupled-Resonator Arrays T. Shi, CPS, Phys. Rev. B 79, 205111 (2009)
5.Quantum switch for single-photon transport in a coupled superconducting transmission-line-resonator array J.Q. Liao, J.F. Huang, Y. Liu, L.M. Kuang, CPS, Phys. Rev. A 80, 014301(2009)
6.Observable Topological Effects of Mobius Molecular Devices Nan Zhao, H. Dong, Shuo Yang, CPS, Phys. Rev. B 79, 125440 (2009)
7. Möbius graphene strip as a topological insulator Z. L. Guo, Z. R. Gong, H. Dong, CPS, Phys. Rev. B 80, 195310 (2009)
1. Controlling Quasibound States in 1D Continuum Through Electromagnetic Induced Transparency Mechanism Z. R. Gong, H. Ian, Lan Zhou, CPS, Phys. Rev. A 78, 053806 (2008)
2. Intrinsic Cavity QED and Emergent Quasi-Normal Modes for Single Photon H. Dong, Z. R. Gong, H. Ian, L. Zhou, CPS, Phys. Rev. A 79, 063847(2009)
3. Quantum super-cavity with atomic mirrors Lan Zhou, H. Dong, Yu-xi Liu, CPS, F.Nori. Phys. Rev. A 78, 063827 (2008)
4. Lehmann-Symanzik-Zimmermann Reduction Approach to Multi-Photon Scattering in Coupled-Resonator Arrays T. Shi, CPS, Phys. Rev. B 79, 205111 (2009)
5.Quantum switch for single-photon transport in a coupled superconducting transmission-line-resonator array J.Q. Liao, J.F. Huang, Y. Liu, L.M. Kuang, CPS, Phys. Rev. A 80, 014301(2009)
6.Observable Topological Effects of Mobius Molecular Devices Nan Zhao, H. Dong, Shuo Yang, CPS, Phys. Rev. B 79, 125440 (2009)
7. Möbius graphene strip as a topological insulator Z. L. Guo, Z. R. Gong, H. Dong, CPS, Phys. Rev. B 80, 195310 (2009)
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Quantum information and future quantum devices
Emergent quantum phenomenain artificial structures and meta-materials
Quantum information Quantum coherent devices
Based on whole wave function rather than state density only:
Phase effect dominated
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From electronic to single electron transistor (SET)
based on current and voltage from the density of electrons rather than phases of the states
Controlling quantum state at the level of single electron
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All optical device in quantum level: Controlling one photon by one photon
Optical switch to single photon transistor (SPT)
http://www.gizmag.com/optical-transistor-made-from-single-molecule/12157/
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Why controlling photon by photon is difficult ?
No direct inter-photon interaction and direct coupling to external E.M field
according to QED
Photon self interaction must be mediated by some massive particles in higher order processes
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Single photon based devices
• Single-photon sourceAn ideal triggered source of single photon emits one and only one photon in each pulse
distributed-Bragg- reflector (DBR) cavity
Photonic-crystal cavity
Our proposal based on superconducting artificial atoms ( PRB 75, 104516 2007)
• Single-photon detection Toshiba setup single photon detector
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Signature of single photon by its statistics
A regulated sequence of optical pulses that contain one-and-only-one photon
2
2
2 2
1. , g (0)>1, superPoissonian, classical2. , g ( )=1, Poissonian, classical3. , g (0)<g ( )<1, subPoissonian, quantum
n nn nn n
τ
τ
Δ >
Δ =
Δ <
2)2(
)(:)()(:
)(tItItI
gτ
τ+
=
1
0 τ
1.
2.
3.
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Single photon transistor (SPT) proposal
D. E. Chang et al , Nature Physics, 3,807(2007)
The setup was based on the theory by a series papers in S.H. Fan, et. al (Stanford), e.g., J. T. Shen and S. Fan, Phys. Rev. Lett. 95, 213001 (2005); 98, 153003 (2007); ibid. 98, 153003 (2007);Opt. Lett. 30, 2001 (2005)
Model : Linear waveguide coupled to a local two-level system
With electromagnetically induced transparency (EIT) mechanism
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Our questions about this SPT Setup
One –shot control : one photon by one photon?
No, nly
strong light controls the EIT
Wide band or narrow band ?
Narrow one due to the single resonate point
Localize photon for quantum memory ?
No, this localization need bound state of Photon !
The linear dispersion that could not trap photon
Dirac Type particle ,Klein paradox
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Our questions about this SPT Setup
Evanesce wave coupling for Photonic crystal defect cavity
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g
e
Controlling photons with local atoms
Quantum Devices
Photon transistor\switch
Quantum storage
Photonic logic device Physics:
Lee-Fano-Aderson model Quasi-Normal Mode Quasi-Bound State Feshbach Resonance
Physical ImplementationCircuit QED with Superconducting qubitPhotonic Crystal Defect cavityCoupled Nanomechanical resonators
Bethe AnsatzDiscrete Coordinate Scattering Equation Quantum Field Theory
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kk cos2ξω −=Ω kk cos2ξω −=Ω
kk ≈sin
2/1cos 2kk −≈
Higher E
Low E
Simulating waveguide in high energy limit
Tight-binding boson model
Non-Linear dispersion
0 π2/π− 2/π
( )1.... . .c j jj
H a aξ ++= − +∑ h c
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CRA Based single photon transistor (SPT)
L. Zhou, Z. R. Gong, Y.X. Liu, C. P. Sun, F. Nori, Phys. Rev. Lett
101, 100501 (2008)
g
e
Hc ∑j
ajaj − ∑
jaj
aj1 h. c.
HI |e⟨e| Ja0† |g⟨e| |e⟨g|a0,
Фx
Local controllerCircuit QED setup
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Discrete coordinate scattering equation
( ) 0 0k k j kej
E u j a g u e+= +∑
Stationary eigen-state
| |k k kH EΩ ⟩ = Ω ⟩
Vacuum state of the cavity field
Single-photon amplitude
Excited state amplitude
)0()(
)]1()1([)()( 0
kkek
jkekkkk
JuuE
JujujujuE
=Ω−
+−++−=− δξω
Two channel scattering equation
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( ) ( ) ( ) ( )( ) 1 1k k k k kV E u j u j u jω ξΩ − − = − + + −⎡ ⎤⎣ ⎦
Resonate potential in effective scattering equation
20( ) j
kk
JV E
Eδ
=−Ω
Resonance Potential
Energy dependent
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Working mechanism of SPT
Ω<kE Ω=kEΩ>kE
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g
e
Solution 1: 2 bound photon states
, 0( )
, 0
ikx
ikx
Ae xu j
Ae x
−⎡ ⎤>= ⎢ ⎥<⎣ ⎦
E 2J
E g2
E − 2 − 4J2
ω
E − g2
E − 2 − 4J2
2Jω +
1BE
2Jω −
2BE
2J
2J
2
2 0ik gE JeE
ω −− + − =−Ω
2 cosE J kω= −
2E Jω< −
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For j<0
For j>0
( ) ikjikjLk reeju −+=
( ) ikjRk seju =
( ) 2
2
cos2sin2 JkkiJr
−−Ω−=
ξωξ
The boundary condition at j=0
Solution 2: single photon scattering
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( )[ ] 4222
4
4)(
JJR
+ΔΔ−Ω−−=Δ
ωξ
kcos2ξω −Ω−=Δ
Breit-Wigner and Fano
line shape
Phase Diagram of reflectionhigh energy limit
Low energy lim
it
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Super-cavity: analog of super-lattice
Super-cavity:
g
e
g
e
Zhou, Dong, Liu, Sun, Nori
Phys. Rev. A 78, 063827
(2008)
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Wide-Band Scattering of Single Photon
Yue Chang, Z. R. Gong, C. P. Sun
. arXiv:1005.2274
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Two photon transport in CRA waveguide
Two photon effect:
The very quantum nature of light
T. Shi and C. P. Sun, Phys. Rev. B 79, 205111 (2009); arXiv:0907.2776.
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Tow photons in one dimension
Anti bunching single photon case two photon case
Photon blockadePhoton blockade
T. Shi, CPS, arXiv:0907.2776(2009)
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Signature of photon blockade via statistics
A two photon interference effect, tends to enhance the single photon effect for single photon counting or source
2
2
2 2
1.g (0)>1, No Blockade2.g ( )=1, No Blocade3.g ( )<g (0)<1, Blockade
τ
τ
(2) ( )g τ1
0 τ
1.
2.
3.
Photon bunching
Photon antibunchingPhoton antibunching
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Photon BunchingPhoton Bunching
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Photon AntiPhoton Anti--BunchingBunching
1
0 τ
2)2(
)(:)()(:
)(tItItI
gτ
τ+
=
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Coulomb (electron) blockade
Coulomb interaction prevents electron from tunneling to Island
1.
Non-linear potential
2.
For certain gate voltage
2
2QCH =
2( )2
Q eCH −=
2 2( ) ( /2)2 2
0 ( )0 ( )
Q e Q e Q eC C CE
E tunnelingE no tunneling
− −Δ = − =
Δ <Δ >
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Photonic analog of Coulomb blockade effect
Strong repulsive interaction of photons is induced by nonlinear medium effectively the excitation of medium by a first photon can block the transport of a second photon.
nonlinear medium
† † 2( )H aa k aaξ=− +
Imamoglu, A.,et
al . Rev. Lett. 79, 1467 (1997).
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Mechanism of photon blockade
λ +(0)2
ω c
g0c
λ −(0)2
λ −(0)1
ω c
λ +(0)1
2g
g
Spectrum of JC model
( ) ( ) | , ( | 1,n n n e n n gλ α β± ± ±= ⟩ + + ⟩
2 21( ) ( ) ( ) 42 c cn n ngλ ω ω± = Ω+ − ± Ω− +
2 2 2 2
(2) (1)
( ) 16 ( ) 4
2 ( resonance)c
c
E
g g
g
λ λ
ω ω ω
ω
− +Δ = −
= − Ω− + + Ω− +
= −
K. M. Birnbaum
et al., Nature (London) 436, 87 (2005))
c gω −
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ω c
ω c
Anti-bouncing means photon blockade?
K. M. Birnbaum
et al., Nature (London) 436, 87 (2005))
λ +(0)2
ω c
g0c
λ −(0)2
λ −(0)1
ω c
λ +(0)1
2g
g
c gω −
EΔ
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Mechanism and Experiment of photon blockade
K. M. Birnbaum
et al., Nature (London) 436, 87 (2005))
U
P B S
1D
e
g 2D
B S
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Photon blockade due to anharmonicity
of energy levels
Transmission line coupled to nonlinear Nano-mechanical resonator via quantum transducer setup [CPS, L. F. Wei, Y Liu, F. NoriPhys. Rev. A 73, 022318 (2006)]
Y.D. Wang, CPS C. Bruder, in preparation, 2010
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2. Numeircal
Master equation approache.g., R. J. Brecha et al., Phys. Rev. A 59, 2392 (1999).
1.Quantum trajectory approach:L. Tian
and H. J. Carmichael, Phys. Rev. A 46, 6801 (1992).
3.Mean field approach: K. Srinivasan
and O. Painter, Phys. Rev. A 75, 023814 (2007).
4. Exact solution with Bethe Ansatz
and QFT
J. T. Shen
, S. Fan, Phys. Rev. Lett. 98, 153003 (2007);
L. Zhou et al.,Phys. Rev. Lett. 101, 100501 (2008); H. Dong et al., Phys. Rev. A 76, 063847 (2009); T. Shi and C. P. Sun, Phys. Rev. B 79, 205111 (2009); arXiv:0907.2776.
Theoretical approaches for two photon
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e
g e
g
Duality of two configurations for two photon
Side-coupling case Direct-coupling case
Reflection of photons in the side-coupling case = Transmission of photons in the direct-coupling case
J. T. Shen and S. Fan, Phys. Rev. A 79, 023837 (2009).
HW ∑k kakak
HJC caa |e⟨e| ga|g⟨e| a|e⟨g|,
HI V∑kaka H. c. / L
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Lehmann-Symanzik-Zimmermann Reduction in QFT
Two -photon effect T. Shi, CPS, Phys. Rev. B 79, 205111 (2009)
1 2 1 2 1 2 1 2
1 1 2 2 2 1 1 2
; ; ,
p p k k p p k k
p k p k p k p k
S iT
S S S S
= +
+
,pk k kpS t δ=1 2
1 2 1 2
4 4 2,
2 1 11,2
( ) [( 2 )( 2 ) 4 ] .( ) ( )( )
p p Ep p k k
s i s i ss s i
E V g E E gTE k p
α δ απ λ λ λ
+
=± =± =
− −Ω − Ω − −=
− − −∏ ∏∏
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QFT Calculations 1
T. Shi, Sanhui Fan, C. P. Sun, Phys. arXiv (2010).
|Xout |tout |rout |rtout
|tout dx 1dx 2 t2x 1 , x2aR x1aR
x 2|0|g
|rout dx 1dx 2r2x 1 , x 2aL x 1aL
x 2|0|g
|rtout dx 1dx 2rt2x 1 , x 2aL x 1aR
x 2|0|g
1 2
1 2
| ,
out inX S X S k kE k k= =
= +
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QFT Calculations 2
T. Shi, Sanhui Fan, C. P. Sun, Phys. arXiv (2010).
2(2)2( ) ( , ) /g t x x Dτ τ= +
For S=L,R,
t2x 1, x 2 12 eiExc t̄ k1
t̄ k2cosΔkx − F, x,
4 41 1,2
1,21 1 2 1
( 2 )exp[ ( )]( , ) ;
4( ) [( ) ( )]
Es s s
s is i s
V g s E i xF x
E kλ λ
λλ λ λ λ
=± −
=± =+ −
− −∑=
− − −∏ ∏
(2) ( ) ( ) ( ) ( ) ( ) |out S S S S outG S a x a x a x a x Sτ τ τ+ += + +
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-10 0 100
4
8
τ
gH2LHτL−
1
-20 0 200
0.5
1
τ
gH2LHτL
5 10 15-1
258
11
Eê2
gH2LH0L
2T
( )a
( )c
( )b
( )d
kΔpΔ 110−
210
510
810
1110
anti-bunching=blockade
large bunching
Strong coupling regime :
2g V
10aω ω= =
12E λ −= 12
E λ +=
(2) ( ) 1g τ −
R=Reflection T=Transmission
RT
R T R T
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2g V
Weak coupling regime :
9.5 10 10.50
4
8
12
Eê2
gH2LH0L
2T
kΔpΔ 010
410
810
1210
kΔpΔ
-20 0 200
0.5
1
τ
gH2LHτL
-10 -5 0 5 100.00.51.01.52.02.5
τ
gH2LHτL−
1
( )a
( )c
( )b
( )d
photon blockade effect vanishes
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Reflected anti-Bouncing photons
T. Shi, CPS, Phys. Rev. B 79, 205111 (2009);2010,in Arxive
reflection
2nd order coherence
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Summary for two photon
The two photon transports in waveguide coupled to a cavity embedded a TLS : Exact solution by LSZ reduction.
Photon blockade effect in strong coupling regime.
Vanishing of Photon blockade effect in weak coupling regime.
Analytic results agree with observations in recent experiment
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Towards active manipulation for photon
via
•Quantum Zeno dynamics•Photonic Feshbach
Resonance
•Induced gauge field with Mobius
topology
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Active control via quantum Zeno dynamics
High frequency modulation
Band structure and bound states in frequency Domain
a → At a cost
PHYSICAL REVIEW A 80, 062109 2009
L.Zhou ,S. Yang ,Y-x Liu ,C. P. Sun, F. Nori
0[ cos( )] | | | | h.c. ....aH t e e G J e gω ννΩ⎛ ⎞= +Ω ⟩⟨ + ⟩⟨ + +⎜ ⎟
⎝ ⎠I
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Dynamic Quantum Zeno Effect
( )exp sin ( )exp( )n nix J x inγ γ= ∑
( )
exp[ ( sin ] | | h.c.,
| | h.c.,i n tn
n
H G i t e g
G J e e gν
νν
ν
+∞−Δ
=−∞
Ω= Δ − ⟩⟨ +
Ω⎛ ⎞= ⟩⟨ +⎜ ⎟⎝ ⎠
∑
I
0 | | h.c.,H G J e gνΩ⎛ ⎞≈ ⟩⟨ +⎜ ⎟
⎝ ⎠I
/ 2.4048, 5.5201,...νΩ =
Decoupling at the zeros of some Bessel function
!!
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Numerical : Quantum Zeno Switch for SPT
Photon Delocalization from bound state due to Zeno effect
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Photonic analog of Feshbach
Resonance
Predicted in Nuclear physics
1961
experiment with cold atoms
1998both in MIT !
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Wave Equation of Single Photon in H-type
E − auaj −Jauaj 1 uaj − 1 gaua0 gbub0E −
gaj,0
E − bubj −Jbubj 1 ubj − 1 gaua0 gbub0E −
gbj,0
Bound state
exp( ), 0( )
exp( ) exp( ), 0a
s ik j ju j
ik j r ik j j′ >⎛ ⎞
= ⎜ ⎟′ ′+ − <⎝ ⎠
ubj B exp−ikj, j 0B expikj, j 0
s 1 − B gagb
JbJa
sin ksin k ′ .
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2a aJω +
1aE
2aE
2a aJω −
aω
2b bJω +
1bE
2bE
2b bJω −
bω
Photonic Feshbach
Resonance
b
A scattering state in chain a
and a bound state chain b
.
S=0, Total Reflection
2
2 0ikb a bb b
s g g gE J eB E E
ω −= − + − =−Ω −Ω
2
2 0ikb a bb b
s g g gE J eB E E
ω −= − + − =−Ω −Ω
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Numerical with FDTD
Without bound state in another chain
With bound state forming in another chain
Coupled cavity arrays with defect in photonic crystal
FDTD = Finite-
difference time-domain
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How to have more controllable parameters for photon
According quantum electrodynamics (QED), no direct interaction exist between two photons , thus magnetic or electric fields could not control the photon straightforwardly.
In this sense, photon is very different from electron
Motivated by AB effect , we use the non-trivial spatial topology to induced an equivalent field for photon
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ϕϕϕϕ
21=φ( ) ( )ϕϕ
ϕΨ=Ψ⎟⎟
⎠
⎞⎜⎜⎝
⎛+
∂∂
− Ei2
21
( ) ( )πϕϕ 2+Ψ=Ψ
( ) ( )ϕψϕ ϕ 2/ie−=Ψ
( ) ( )ϕψϕψϕ
E=∂∂
− 2
2
( ) ( )πϕψϕψ 2+−=
Gauge transf.
Periodic, single-valued
anti-periodic, multi-valued
Aharanov–Bohm
effect in a mesoscopic
ring
How about a more complicated topologically non-trivial boundary ??
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Tight binding boson model
with Mobius
topology
Mobius
boundary condition:
,Nj
N
j jj
j j
aA
b
VVε
ε
⎛ ⎞= ⎜ ⎟⎝ ⎠⎛ ⎞
= ⎜ ⎟−⎝ ⎠M
⎟⎟⎠
⎞⎜⎜⎝
⎛⎟⎟⎠
⎞⎜⎜⎝
⎛=⎟⎟
⎠
⎞⎜⎜⎝
⎛
0
0
0110
ba
ba
N
N
1 111 12
j j
j j
c ad b⎛ ⎞ ⎛ ⎞⎛ ⎞
=⎜ ⎟ ⎜ ⎟⎜ ⎟−⎝ ⎠⎝ ⎠ ⎝ ⎠
Cut- off of upper band in transmission spectrum
c-ring
d-ring
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Physical Realization of Mobius
systems
Chemical Reviews (2006)Tetrahedron Lett. (1964)
J. Am. Chem. Soc. (1982)
Boson:
heating a bundle of photonic crystal fibers been
Fermion: synthesizing aromatic hydrocarbons with twisted Pi-electrons
Nature (2002)
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Non-Abelian
induced gauge field in continuous limit
The Mobius
boundary condition induce an effective magnetic flux in the “conduction band”.
In the pseudo-spin representation
( ) ⎟⎟⎠
⎞⎜⎜⎝
⎛=+=
00021
41zσφ
D. Loss, P. Goldbart, A. V. Balatsky, Phys. Rev. Lett. 65, 1655 (1990)
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Suppression of conduction band transmission
Conclusions also valid to the fermion
system
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Acknowledgements
+ some regular visitors
Students:
Hui Dong, Tao Shi, Dazi
Xu ,
Yue Chang,Jin-Feng
Huan
Post DocDr. Qing Ai
Franco Nori (Riken & Univ. Michigan
), Shan-Hui Fan (Univ. Stanford
)
Lan Zhou (HNNU), Yu-xi Liu (Tsinghua
Univ) [ my previous Post docs]
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