1. Functional renormalization – concepts and prospects

2. physics at different length scales microscopic theories : where the laws are formulated microscopic theories : where the laws are formulated effective theories : where observations are made effective theories : where observations are made effective theory may involve different degrees of freedom as compared to microscopic theory effective theory may involve different degrees of freedom as compared to microscopic theory example: the motion of the earth around the sun does not need an understanding of nuclear burning in the sun example: the motion of the earth around the sun does not need an understanding of nuclear burning in the sun

3. QCD : Short and long distance degrees of freedom are different ! Short distances : quarks and gluons Short distances : quarks and gluons Long distances : baryons and mesons Long distances : baryons and mesons How to make the transition? How to make the transition? confinement/chiral symmetry breaking confinement/chiral symmetry breaking

4. collective degrees of freedom

5. Hubbard model Electrons on a cubic lattice Electrons on a cubic lattice here : on planes ( d = 2 ) here : on planes ( d = 2 ) Repulsive local interaction if two electrons are on the same site Repulsive local interaction if two electrons are on the same site Hopping interaction between two neighboring sites Hopping interaction between two neighboring sites

6. In solid state physics : “ model for everything “ Antiferromagnetism Antiferromagnetism High T c superconductivity High T c superconductivity Metal-insulator transition Metal-insulator transition Ferromagnetism Ferromagnetism

7. Antiferromagnetism in d=2 Hubbard model temperature in units of t antiferro- magnetic order parameter T c /t = 0.115 U/t = 3 T.Baier, E.Bick,…

8. Collective degrees of freedom are crucial ! for T < T c nonvanishing order parameter nonvanishing order parameter gap for fermions gap for fermions low energy excitations: low energy excitations: antiferromagnetic spin waves antiferromagnetic spin waves

9. effective theory / microscopic theory sometimes only distinguished by different values of couplings sometimes only distinguished by different values of couplings sometimes different degrees of freedom sometimes different degrees of freedom

10. Functional Renormalization Group describes flow of effective action from small to large length scales perturbative renormalization : case where only couplings change, and couplings are small

11. How to come from quarks and gluons to baryons and mesons ? How to come from electrons to spin waves ? Find effective description where relevant degrees of freedom depend on momentum scale or resolution in space. Find effective description where relevant degrees of freedom depend on momentum scale or resolution in space. Microscope with variable resolution: Microscope with variable resolution: High resolution, small piece of volume: High resolution, small piece of volume: quarks and gluons quarks and gluons Low resolution, large volume : hadrons Low resolution, large volume : hadrons

13. / Wegner, Houghton

14. effective average action

15. Effective average potential : Unified picture for scalar field theories with symmetry O(N) in arbitrary dimension d and arbitrary N linear or nonlinear sigma-model for chiral symmetry breaking in QCD or: scalar model for antiferromagnetic spin waves (linear O(3) – model ) fermions will be added later fermions will be added later

16. Effective potential includes all fluctuations

17. Scalar field theory Scalar field theory

18. Flow equation for average potential

19. Simple one loop structure – nevertheless (almost) exact

20. Infrared cutoff

21. Partial differential equation for function U(k,φ) depending on two ( or more ) variables Z k Z k = c k -η

22. Regularisation For suitable R k : Momentum integral is ultraviolet and infrared finite Momentum integral is ultraviolet and infrared finite Numerical integration possible Numerical integration possible Flow equation defines a regularization scheme ( ERGE –regularization ) Flow equation defines a regularization scheme ( ERGE –regularization )

23. Integration by momentum shells Momentum integral is dominated by q 2 ~ k 2. Flow only sensitive to physics at scale k

24. Wave function renormalization and anomalous dimension for Z k (φ,q 2 ) : flow equation is exact !

25. Flow of effective potential Ising model CO 2 T * =304.15 K p * =73.8.bar ρ * = 0.442 g cm-2 Experiment : S.Seide … Critical exponents

26. Critical exponents, d=3

27. Solution of partial differential equation : yields highly nontrivial non-perturbative results despite the one loop structure ! Example: Kosterlitz-Thouless phase transition

28. Essential scaling : d=2,N=2 Flow equation contains correctly the non- perturbative information ! Flow equation contains correctly the non- perturbative information ! (essential scaling usually described by vortices) (essential scaling usually described by vortices) Von Gersdorff …

29. Kosterlitz-Thouless phase transition (d=2,N=2) Correct description of phase with Goldstone boson Goldstone boson ( infinite correlation length ) ( infinite correlation length ) for T<T c for T<T c

30. Running renormalized d-wave superconducting order parameter κ in Hubbard model κ - ln (k/Λ) TcTc T>T c T<T c C.Krahl,… macroscopic scale 1 cm

31. Renormalized order parameter κ and gap in electron propagator Δ 100 Δ / t κ T/T c jump

32. Temperature dependent anomalous dimension η T/T c η

33. Effective average action and exact renormalization group equation

34. Generating functional Generating functional

35. Loop expansion : perturbation theory with infrared cutoff in propagator Effective average action

36. Quantum effective action

37. Exact renormalization group equation

38. Truncations Truncations Functional differential equation – cannot be solved exactly cannot be solved exactly Approximative solution by truncation of most general form of effective action most general form of effective action

41. Exact flow equation for effective potential Evaluate exact flow equation for homogeneous field φ. Evaluate exact flow equation for homogeneous field φ. R.h.s. involves exact propagator in homogeneous background field φ. R.h.s. involves exact propagator in homogeneous background field φ.

42. changing degrees of freedom

43. Antiferromagnetic order in the Hubbard model A functional renormalization group study T.Baier, E.Bick, …

44. Hubbard model Functional integral formulation U > 0 : repulsive local interaction next neighbor interaction External parameters T : temperature μ : chemical potential (doping )

45. Fermion bilinears Introduce sources for bilinears Functional variation with respect to sources J yields expectation values and correlation functions

46. Partial Bosonisation collective bosonic variables for fermion bilinears collective bosonic variables for fermion bilinears insert identity in functional integral insert identity in functional integral ( Hubbard-Stratonovich transformation ) ( Hubbard-Stratonovich transformation ) replace four fermion interaction by equivalent bosonic interaction ( e.g. mass and Yukawa terms) replace four fermion interaction by equivalent bosonic interaction ( e.g. mass and Yukawa terms) problem : decomposition of fermion interaction into bilinears not unique ( Grassmann variables) problem : decomposition of fermion interaction into bilinears not unique ( Grassmann variables)

47. Partially bosonised functional integral equivalent to fermionic functional integral if Bosonic integration is Gaussian or: solve bosonic field equation as functional of fermion fields and reinsert into action

48. fermion – boson action fermion kinetic term boson quadratic term (“classical propagator” ) Yukawa coupling

49. source term is now linear in the bosonic fields

50. Mean Field Theory (MFT) Evaluate Gaussian fermionic integral in background of bosonic field, e.g.

51. Effective potential in mean field theory

52. Mean field phase diagram μ μ TcTc TcTc for two different choices of couplings – same U !

53. Mean field ambiguity TcTc μ mean field phase diagram U m = U ρ = U/2 U m = U/3,U ρ = 0 Artefact of approximation … cured by inclusion of bosonic fluctuations J.Jaeckel,…

54. Rebosonization and the mean field ambiguity

55. Bosonic fluctuations fermion loops boson loops mean field theory

56. Rebosonization adapt bosonization to every scale k such that adapt bosonization to every scale k such that is translated to bosonic interaction is translated to bosonic interaction H.Gies, … k-dependent field redefinition absorbs four-fermion coupling

57. Modification of evolution of couplings … Choose α k such that no four fermion coupling is generated Evolution with k-dependent field variables Rebosonisation

58. …cures mean field ambiguity TcTc U ρ /t MFT Flow eq. HF/SD

59. conclusions Flow equation for effective average action: Does it work? Does it work? Why does it work? Why does it work? When does it work? When does it work? How accurately does it work? How accurately does it work?

60. end

61. Flow equation for the Hubbard model T.Baier, E.Bick, …

62. Truncation Concentrate on antiferromagnetism Potential U depends only on α = a 2

63. scale evolution of effective potential for antiferromagnetic order parameter boson contribution fermion contribution effective masses depend on α ! gap for fermions ~α

64. running couplings

65. unrenormalized mass term Running mass term four-fermion interaction ~ m -2 diverges -ln(k/t)

66. dimensionless quantities renormalized antiferromagnetic order parameter κ

67. evolution of potential minimum -ln(k/t) U/t = 3, T/t = 0.15 κ 10 -2 λ

68. Critical temperature For T 10 -9 size of probe > 1 cm -ln(k/t) κ T c =0.115 T/t=0.05 T/t=0.1

69. Below the critical temperature : temperature in units of t antiferro- magnetic order parameter T c /t = 0.115 U = 3 Infinite-volume-correlation-length becomes larger than sample size finite sample ≈ finite k : order remains effectively

70. Pseudocritical temperature T pc Limiting temperature at which bosonic mass term vanishes ( κ becomes nonvanishing ) It corresponds to a diverging four-fermion coupling This is the “critical temperature” computed in MFT !

71. Pseudocritical temperature T pc μ TcTc MFT(HF) Flow eq.

72. Below the pseudocritical temperature the reign of the goldstone bosons effective nonlinear O(3) – σ - model

73. critical behavior for interval T c < T < T pc evolution as for classical Heisenberg model cf. Chakravarty,Halperin,Nelson

74. critical correlation length c,β : slowly varying functions exponential growth of correlation length compatible with observation ! at T c : correlation length reaches sample size !

75. critical behavior for order parameter and correlation function

76. Mermin-Wagner theorem ? No spontaneous symmetry breaking of continuous symmetry in d=2 ! of continuous symmetry in d=2 !

77. Proof of exact flow equation