1. Correlations in quantum dots: How far can analytics go?
Vyacheslavs (Slava) Kashcheyevs
Collaboration: Amnon Aharony (BGU+TAU) Ora Entin-Wohlman (BGU+TAU) Avraham Schiller (Hebrew Univ.)
December 18th, 2006

2. Outline Physics of the Anderson model Equations of motion
Relevant energies and regimes
The plethora of methods
Equations of motion
Self-consistent truncation
Gauging quality in known limits
Anderson model for double quantum dots
Charge location as a pseudo-spin
Diverse results in a unified way
The first is a pillar-builder. No equations
One is more about the method (lot’s of equations),
the other one – on results (all together)

3. Quantum dots Tune: gate potentials, temperature, field…
Lead QD
Lead
Gates
Electron gas plane
GaAs
AlGaAs
Tune: gate potentials, temperature, field…
Measure: I-V curves, conductance G…
Aharonov-Bohm interferometry, dephasing, coherent state manipulation…

4. Building models Quantum dots Tunneling Hamiltonian approach
Mesoscopic: many levels involved, statistical description
Microscopic: few levels, individual properties
Tunneling Hamiltonian approach

5. Anderson model: the leadsμ
Non-interacting in the sense of Fermi liquid.
Continuum, equilibrium, chemical potetnial
Lead
Lead
A set of energy levels

6. Anderson model: the dotμ
Also a level. epsilon_0 >> mu – empty, does down, gets occupied, occupied.
Lead QD
Lead
An energy level ε0

7. Anderson model: the dotε0 1 2 n
f (ε0) T μ μ
Also a level. epsilon_0 >> mu – empty, does down, gets occupied, occupied.
A Fermion! fermi-Dirac statistic
Lead QD
Lead
An energy level ε0

8. Anderson model: the dotε0 1 2 n
f (ε0) T μ μ
A Fermion! fermi-Dirac statistic. remember spin
Lead QD
Lead
An energy level ε0

9. Anderson model: the dot
Spin-charge separation or “Mott transition” ε0 1 2 n
f (ε0) T U U μ μ μ
Interactuions
Interactions!
Lead QD
Lead
An energy level ε0

10. Anderson model: tunnelingε0 1 2 n VR U VL Γ Γ μ μ
Quantum fluctuations: – of charge Γ > T – of spin U > Γ > T
Interactuions
Lead QD
Lead
Tunneling
Tunneling rate Γ ~ ρ|V|2

11. Anderson model: spin exchangeε0 1 2 n U μ μ
Interactuions
Lead QD
Lead
Fix the spin on the dot
Opposite spin in the leads can lower energy!

12. Anderson model: spin exchangeε0 1 2 n U μ μ
Virtual transition:
Interactuions
Lead QD
Lead
Fix the spin on the dot
Opposite spin in the leads can lower energy!

13. Anderson model: spin exchangeε0 1 2 n U μ μ
Virtual transition:
Interactuions
Lead QD
Lead
Fix the spin on the dot
Same spin can’t go!

14. Effective Hamiltonian: Kondo
Interactuions
Lead QD
Lead
Ferromagnetic exchange interaction!

15. Effective Hamiltonian: Kondo
<S>
½ – O(J)
1/2 ? h J
Interactuions
Lead QD
Lead
Ferromagnetic exchange interaction!
← can fix S with h >> J

16. The Kondo effect
<S>
½ – O(J)
1/2 ?
~ h/TK h TK J
Interactuions
Lead QD
Lead
singlet-triplet splitting
|↑↓> and |↓↑> are degenerate (Sz=0 of S=0,1)
except for virtual excitations ~ J !

17. Outline Physics of the Anderson model Equations of motion
Relevant energies and regimes
The plethora of methods
Equations of motion
Self-consistent truncation
Gauging quality in known limits
Anderson model for double quantum dots
Charge location as a pseudo-spin
Diverse results in a unified way
The first is a pillar-builder. No equations
One is more about the method (lot’s of equations),
the other one – on results (all together)

18. Methods Perturbation theory (PT) in Γ, in U
in U – regular & systematic; not good for U>> Γ.
in Γ – breaks down at resonances & in Kondo regime
Fermi liquid: good at T<TK, exact sum rules for T=0
Equations of motion (EOM) for Green functions
exact for U; a low order (Hartree mean field) gives local moment
as good as PT when PT is valid
can we get Kondo at higher orders?
Renormalization Group
perturbative (in Γ) RG => Kondo Hamiltonian + PM scaling
perturbative (in U) RG => functional RG (semi-analytic)
Wilson’s Numerical RG – high accuracy, but numerics only
Bethe ansatz: exploits integrability
exact (!) solution, many analytic results
integrability condition too restrictive, finite very T laborious

19. Outline Physics of the Anderson model Equations of motion
Relevant energies and regimes
The plethora of methods
Equations of motion
Self-consistent truncation
Gauging quality in known limits
Anderson model for double quantum dots
Charge location as a pseudo-spin
Diverse results in a unified way
The first is a pillar-builder. No equations
One is more about the method (lot’s of equations),
the other one – on results (all together)

20. The Green functions Retarded Advanced Spectral function Zubarev (1960)
step function
Retarded
Advanced
Spectral function
grand canonical

21. Dot’s GF Spectral function → Density of states
Occupation number → Local charge & spin
Friedel-Langreth sum rule (T=0)
conductance at T=0 is proportional ~ ρ(μ)!

22. Equations of motion
Example: 1st equation for

23. spin-flip excitations
Full solution for U=0
Lead self-energy function
ε0 +U ε0
ω=0 Fermi
hole excitations
electron excitations
spin-flip excitations
Lorenzian DOS
bandwidth D Γ
Large U should bring

24. Full hierarchy …

25. A general term
Dworin (1967)
m = 0,1, 2… lead operators
n = 0 – 3 dot operators
Contributes to a least m-th order in Vk and (n+m–1)/2-th order in U !
Certain order of EOM truncation ↔ certain order of perturbation theory!

26. Decoupling

27. Demand full self-consistency
Decoupling
“D.C.Mattis scheme”:
Theumann (1969)
Use mean-field for at most 1 dot operator:
Use values
Meir, Wigreen, Lee (1991)
Linear = easy to solve
Fails at low T – no Kondo
Demand full self-consistency
Significant improvement
Hard-to-solve non-linear integral eqs.

28. The self-consistent equations
Zeeman splitting
Level position
The only input
parameters
Self-consistent functions:

29. EOMs: How to solve? In general, iterative numerical solution
Two analytically solvable cases:
and wide band limit: explicit non-trivial solution
particle-hole symmetry point : break down of the approximation

30. Outline Physics of the Anderson model Equations of motion
Relevant energies and regimes
The plethora of methods
Equations of motion
Self-consistent truncation
Gauging quality in known limits
Anderson model for double quantum dots
Charge location as a pseudo-spin
Diverse results in a unified way
The first is a pillar-builder. No equations
One is more about the method (lot’s of equations),
the other one – on results (all together)

31. EOMs: Results Ed / Γ Zero temperature Zero magnetic field & wide band
Energy ω/Γ
Fermi
Zero temperature
Zero magnetic field
& wide band
Level renormalization
Changing Ed/Γ
Looking at DOS:
even
odd

32. Results: occupation numbers
Compare to perturbation theory
Compare to Bethe ansatz
Gefen & Kőnig (2005)
Wiegmann & Tsvelik (1983)
Better than 3% accuracy!

33. Check: Friedel-Langreth sums
No quasi-particle damping at the Fermi surface:
Fermi sphere volume conservation
Good – for nearly empty dot
Broken – in the Kondo valley

34. Results: melting of the peak
2e2/h conduct.
At small T and
near Fermi energy, parameters in the solution combine as
Smaller than the true Kondo T:
~ 1/log2(T/TK)
DOS at the Fermi energy scales with T/TK*
Experiment: van der Wiel et al., Science 289, 2105 (2000)

35. EOMs: conclusions
“Physics repeats itself with a period of T ≈ 30 years” – © OEW
Non-trivial results require non-trivial effort
… and even then they may disappoint someone’s expectations

36. Outline Physics of the Anderson model Equations of motion
Relevant energies and regimes
The plethora of methods
Equations of motion
Self-consistent truncation
Gauging quality in known limits
Anderson model for double quantum dots
Charge location as a pseudo-spin
Diverse results in a unified way
The first is a pillar-builder. No equations
One is more about the method (lot’s of equations),
the other one – on results (all together)

37. Double dots: a minimal model
Two orbital levels
Two leads
Inter-dot
repulsion U
tunneling b
Aharonov-Bohm flux
(wide band)

38. Interesting properties
Charge oscillations / population switching
Transmission zeros / phase lapses
“Correlation-induced” resonances
Konig & Gefen PRB 71 (2005) [PT]
Sindel, Silva, Oreg & von Delft PRB 72 (2005) [NRG & HF]
Meden & Marquardt PRL (2006) [fRG & NRG]s

39. Singular value decomposition
Diagonalize the tunneling matrix:
Define new degrees of freedom
The pseudo-spin is conserved in tunneling!

40. Map to Anderson model Rotated magnetic field! z θ x
Generally Vup <> Vdown – ferromagnetic leads
Generally h is not || to anisotropy axis x z θ
Rotated magnetic field!

41. Special case: an exact result
Degenerate levels:
Spin is conserved → Friedel rule applies:
SIC!
Need a way to get magnetization M !
Local moment,

42. Mapping to Kondo Hamiltonian
Schrieffer-Wolff for U >> Γ,h (local moment)
Anisotropic exchange
Effective field
Anisotropy is RG irrelevant
Silvestrov & Imry PRL (2000)
Martinek et al PRL (2003)

43. Main results An isotropic Kondo model in external field
Local moment
here:
An isotropic Kondo model in external field
Use exact Bethe ansatz
Key quantities
Return back

44. Main results: anisotropic Γ’s
Both competing scales depend on ε0
h ≈ TK => M=1/4
fRG
h = 0

45. Double dots: conclusions
Looking at the right angle makes old physics useful again
Singular value decomposition (SVD) reduces dramatically the parameter space
Accurate analytic expressions for linear conductance and occupations
Future prospects:
more levels
add real spin
non-equilibrium