1. Collaborators: G.Kotliar, Ji-Hoon Shim, S. Savrasov Kristjan Haule, Physics Department and Center for Materials Theory Rutgers University Electronic Structure of Strongly Correlated Electron Materials: A Dynamical Mean Field Perspective. Miniworkshop on New States of Stable and Unstable Quantum Matter, Trst 2006

2. Application of DMFT to real materials (Spectral density functional approach). Examples: –alpha to gamma transition in Ce, optics near the temperature driven Mott transition. –Mott transition in Americium under pressure –Antiferromagnetic transition in Curium Extensions of DMFT to clusters. Examples: –Superconducting state in t-J the model –Optical conductivity of the t-J model Overview

3. V2O3V2O3 Ni 2-x Se x  organics Universality of the Mott transition First order MIT Critical point Crossover: bad insulator to bad metal 1B HB model (DMFT):

4. Coherence incoherence crossover in the 1B HB model (DMFT) Phase diagram of the HM with partial frustration at half-filling M. Rozenberg et.al., Phys. Rev. Lett. 75, 105 (1995).

5. DMFT + electronic structure method Effective (DFT-like) single particle Spectrum consists of delta like peaks Spectral density usually contains renormalized quasiparticles and Hubbard bands Basic idea of DMFT: reduce the quantum many body problem to a one site or a cluster of sites problem, in a medium of non interacting electrons obeying a self-consistency condition. (A. Georges et al., RMP 68, 13 (1996)). DMFT in the language of functionals: DMFT sums up all local diagrams in BK functional Basic idea of DMFT+electronic structure method (LDA or GW): For less correlated bands (s,p): use LDA or GW For correlated bands (f or d): with DMFT add all local diagrams

6. f1 L=3,S=1/2 J=5/2 f6 L=3,S=3 J=0 How good is single site DMFT for f systems? f1 L=3,S=1/2 J=5/2 f5 L=5,S=5/2 J=5/2 f6 L=3,S=3 J=0 f7 L=0,S=7/2 J=7/2

7. Cerium

8. Ce overview volumesexp.LDALDA+U  28Å 3 24.7Å 3  34.4Å 3 35.2Å 3 Transition is 1.order ends with CP  isostructural phase transition ends in a critical point at (T=600K, P=2GPa)   (fcc) phase [ magnetic moment (Curie-Wiess law), large volume, stable high-T, low-p]   (fcc) phase [ loss of magnetic moment (Pauli-para), smaller volume, stable low-T, high-p] with large volume collapse  v/v  15 

9. LDA and LDA+U f DOS total DOS volumesexp.LDALDA+U  28Å 3 24.7Å 3  34.4Å 3 35.2Å 3 ferromagnetic

10. LDA+DMFT alpha DOS T K (exp)=1000-2000K

11. LDA+DMFT gamma DOS T K (exp)=60-80K

12. Photoemission&experiment Fenomenological approach describes well the transition Kondo volume colapse (J.W. Allen, R.M. Martin, 1982) A. Mc Mahan K Held and R. Scalettar (2002) K. Haule V. Udovenko and GK. (2003)

13. Optical conductivity * + + K. Haule, et.al., Phys. Rev. Lett. 94, 036401 (2005) * J.W. van der Eb, A.B. Ku’zmenko, and D. van der Marel, Phys. Rev. Lett. 86, 3407 (2001)

14. Americium

15. "soft" phase f localized "hard" phase f bonding Mott Transition? f 6 -> L=3, S=3, J=0 A.Lindbaum, S. Heathman, K. Litfin, and Y. Méresse, Phys. Rev. B 63, 214101 (2001) J.-C. Griveau, J. Rebizant, G. H. Lander, and G.Kotliar Phys. Rev. Lett. 94, 097002 (2005)

16. Am within LDA+DMFT S. Y. Savrasov, K. Haule, and G. Kotliar Phys. Rev. Lett. 96, 036404 (2006) F (0) =4.5 eV F (2) =8.0 eV F (4) =5.4 eV F (6) =4.0 eV Large multiple effects:

17. Am within LDA+DMFT n f =6 Comparisson with experiment from J=0 to J=7/2 “Soft” phase very different from  Ce not in local moment regime since J=0 (no entropy) "Hard" phase similar to  Ce, Kondo physics due to hybridization, however, nf still far from Kondo regime n f =6.2 Different from Sm! Exp: J. R. Naegele, L. Manes, J. C. Spirlet, and W. Müller Phys. Rev. Lett. 52, 1834-1837 (1984) Theory: S. Y. Savrasov, K. Haule, and G. Kotliar Phys. Rev. Lett. 96, 036404 (2006) V=V 0 Am I V=0.76V 0 Am III V=0.63V 0 Am IV

18. Curie-Weiss Tc Trends in Actinides alpa->delta volume collapse transition Same transition in Am under pressure Curium has large magnetic moment and orders antif. F0=4,F2=6.1 F0=4.5,F2=7.15 F0=4.5,F2=8.11

19. EELS & XAS core valence 4d 3/2 4d 5/2 5f 5/2 5f 7/2 Excitations from 4d core to 5f valence Electron energy loss spectroscopy (EELS) or X-ray absorption spectroscopy (XAS) Branching ration B=A 5/2 /(A 5/2 +A 3/2 ) Energy loss [eV] Core splitting~50eV 4d 5/2 ->5f 7/2 4d 3/2 ->5f 5/2 2/3 =-5/2(14-n f )(B-B 0 ) B 0 ~3/5 Measures unoccupied valence 5f states Probes high energy Hubbard bands! gives constraint on n f for given n f, determines

20. LS versus jj coupling in Actinides K.T.Moore, et.al.,PRB in press, 2006 G. Van der Laan, et.al, PRL 93,27401 (2004) J.G. Tobin, et.al, PRB 72, 85109 (2005) Occupations non-integer except Cm Close to intermediate coupling Am under pressure goes towards LS Delocalization in U & Pu-> towards LS   Curium is localized, but close to LS!  =7.9  B not  =4.2  B

21. What is captured by single site DMFT? Captures volume collapse transition (first order Mott-like transition) Predicts well photoemission spectra, optics spectra, total energy at the Mott boundary Antiferromagnetic ordering of magnetic moments, magnetism at finite temperature Qualitative explanation of mysterious phenomena, such as the anomalous raise in resistivity as one applies pressure in Am,..

22. Beyond single site DMFT What is missing in DMFT? Momentum dependence of the self-energy m*/m=1/Z Various orders: d-waveSC,… Variation of Z, m*,  on the Fermi surface Non trivial insulator (frustrated magnets) Non-local interactions (spin-spin, long range Columb,correlated hopping..) Present in DMFT: Quantum time fluctuations Present in cluster DMFT: Quantum time fluctuations Spatially short range quantum fluctuations

23. The simplest model of high Tc’s t-J, PW Anderson Hubbard-Stratonovich ->(to keep some out-of-cluster quantum fluctuations) BK Functional, Exact cluster in k spacecluster in real space

24. t’=0 Phase diagram What can we learn from “small” Cluster-DMFT?

25. Insights into superconducting state (BCS/non-BCS)? J. E. Hirsch, Science, 295, 5563 (2001) BCS: upon pairing potential energy of electrons decreases, kinetic energy increases (cooper pairs propagate slower) Condensation energy is the difference non-BCS: kinetic energy decreases upon pairing (holes propagate easier in superconductor)

26. D van der Marel, Nature 425, 271-274 (2003) cond-mat/0601478 Optical conductivity overdoped optimally doped

27. Bi2212 ~1eV Weight bigger in SC, K decreases (non-BCS) Weight smaller in SC, K increases (BCS-like) Optical weight, plasma frequency F. Carbone et.al, cond-mat/0605209

28. Hubbard model Drude U t 2 /U t-J model J Drude no-U Experiments intraband interband transitions ~1eV Excitations into upper Hubbard band Kinetic energy in Hubbard model: Moving of holes Excitations between Hubbard bands Kinetic energy in t-J model Only moving of holes Hubbard versus t-J model

29. Phys Rev. B 72, 092504 (2005) cluster-DMFT, cond-mat/0601478 Kinetic energy change Kinetic energy decreases Kinetic energy increases Exchange energy decreases and gives largest contribution to condensation energy cond-mat/0503073

30. electrons gain energy due to exchange energy holes gain kinetic energy (move faster) underdoped electrons gain energy due to exchange energy hole loose kinetic energy (move slower) overdoped BCS like same as RVB (see P.W. Anderson Physica C, 341, 9 (2000), or slave boson mean field (P. Lee, Physica C, 317, 194 (1999) Kinetic energy upon condensation J J J J

31. Pengcheng et.al., Science 284, (1999) YBa 2 Cu 3 O 6.6 (Tc=62.7K) 41meV resonance local susceptibility Resonance at 0.16t~48meV Most pronounced at optimal doping Second peak shifts with doping (at 0.38~120meV opt.d.) and changes below Tc – contribution to condensation energy

32. Optics mass and plasma frequency Extended Drude model In sigle site DMFT plasma frequency vanishes as 1/Z (Drude shrinks as Kondo peak shrinks) at small doping Plasma frequency vanishes because the active (coherent) part of the Fermi surface shrinks In cluster-DMFT optics mass constant at low doping doping ~ 1/Jeff line: cluster DMFT (cond-mat 0601478), symbols: Bi2212, F. Carbone et.al, cond-mat/0605209

33. LDA+DMFT can describe interplay of lattice and electronic structure near Mott transition. Gives physical connection between spectra, lattice structure, optics,.... –Allows to study the Mott transition in open and closed shell cases. –In elemental actinides and lanthanides single site LDA+DMFT gives the zeroth order picture 2D models of high-Tc require cluster of sites. Some aspects of optimally doped, overdoped and slightly underdoped regime can be described with cluster DMFT on plaquette: –Evolution from kinetic energy saving to BCS kinetic energy cost mechanism Conclusions

34. Partial DOS 4f 5d 6s Z=0.33

35. Optimal doping: Coherence scale seems to vanish Tc underdoped overdoped optimally scattering at Tc

36. Pseudoparticle insight N=4,S=0,K=0 N=4,S=1,K=(  ) N=3,S=1/2,K=( ,0) N=2,S=0,K=0 A(  )  ’’ (  ) PH symmetry, Large 