Electronic Griffiths phases and dissipative spin liquids - Campinas, Brazil E. M. Darko Tanasković Vlad Dobrosavljević - Magnet Lab/FSU Complex Behavior in Correlated Electron Systems Lorentz Center – Leiden – August 11, 2005
Non-Fermi Liquid behavior in Kondo systems Many disordered heavy fermion systems show anomalous properties, inconsistent with Landau’s Fermi liquid theory (see, e.g., G. Stewart, RMP 73, 797 (2001), E.M., V. Dobrosavljević, to appear in Rep. Prog. Phys. (2005)) UCu5-xPdx La1-xCexCu2.2Si2 M1-xUxPd3 (M=Y,Sc) Andrade et al., PRL 1998 Bernal et al., PRL 1985 Aronson et al., PRL 2001 UCu4Pd
Theoretical scenarios Phenomenological Kondo disorder model (Bernal et al., PRL `95; E.M., V. Dobrosavljević, G. Kotliar, PRL `97): distribution of Kondo temperatures Þ P(TK) Magnetic Griffiths phase (Castro Neto, Castilla, Jones, PRL `98, PRB `00): distribution of fluctuating locally ordered clusters of size N Þ P(N) Spin glass critical point (Sengupta, Georges, PRB `95; Rozenberg, Grempel, PRB `99) Dominated by low TK spins if P(TK=0) ¹0 Kondo disorder model Form of P(TK) is assumed: is there a microscopic mechanism?
Electronic Griffiths phase (E.M., V. Dobrosavljević, PRL `01) Local DOS at the Fermi level (wave function amplitude) fluctuates spatially ® Anderson localization effects TK is exponentially sensitive to the local DOS (Dobrosavljevic, Kirkpatrick, Kotliar, `92) Statistical Dynamical Mean Field Theory (for the Anderson lattice) (Dobrosavljević, Kotliar, PRL `97) A local correlated action at each f-site (U ® ¥ Anderson single-impurity model) Green’s function of conduction electrons with site “j” removed Each f-site gives rise to a local self-energy Sj (wn) for the lattice problem, which is numerically solved
Electronic Griffiths phase (E.M., V. Dobrosavljević, PRL `01) Power law distribution of Kondo temperatures at moderate disorder a=a(W) is tunable with disorder strength (Broad) Griffiths phase induced by the proximity to an Anderson transition NFL if a<1
Generic mechanism of quantum Griffiths phases Exponentially rare events with exponentially low energy scales, e. g., in a random field Ising model (D. Fisher, PRL `92, PRB `95) but also in other systems (Senthil, Sachdev, PRL `96; Castro Neto, Jones, PRB `00; T. Vojta, Schmalian, PRB `05;....) (Poisson) For example, for a fluctuating ferromagnetic droplet of size V (tunneling) Power-law distribution of energy scales (tunneling rates) From this, the usual phenomenology follows, quite independent of the nature of the fluctuators
What is the origin of the electronic GP? Effective model (D. Tanasković, V. Dobrosavljević, E.M., PRB `04) Model with c-site (diagonal) disorder only and Gaussian distribution Infinite coordination limit (z ® ¥) (Dynamical Mean Field Theory) No DOS fluctuations (no Anderson localization effects)! Fixed conduction electron bath
What is the origin of the electronic GP? When ej ® ¥, Usual Griffiths phase behavior! Since disorder W MIT W* insulator Fermi liquid EGP with NFL behavior a<1
How to justify the effective model? In a real lattice, the conduction bath is not fixed but fluctuates randomly To leading order, ReDj(0) fluctuations are gaussian and µ W2 Even if P(ej) is bounded P(ejren) is not! Good agreement between statDMFT and effective model
Problems with the usual scenario Thermodynamic divergences are too strong a»1/W2; experiments show near log behavior (a»1). Proliferation of “free” spins: entropy expected to be quenched by interactions at low T, (probably spin-glass, D. MacLaughlin et al. PRL `01) What is missing? RKKY interactions between (distant) low-TK (unscreened) spins: oscillatory with distance Þ random in magnitude and sign Expect quantum spin-glass dynamics at low T (D. MacLaughlin et al. PRL`01) (E)DMFT formulation: infinite-range spin glass interactions (paramagnetic phase) (Tanasković, Dobrosavljević, E.M., cond-mat/0412100) Self-consistency: Local action: “Bose-Fermi Kondo model” Related work: Burdin, Grempel, Georges, PRB ´02
Question: Will a positive e be self-consistently generated? Single-impurity Bose-Fermi Kondo model (Q. Si, J. L. Smith, EPL `99, A. M. Sengupta, PRB `00) g (RKKY coupling) rcJK (Kondo coupling) ~ e Kondo screened No Kondo effect One spin subject to a fermionic bath and a fluctuating magnetic field (bosonic bath). For c(t)~1/t2-e with e>0, there is a lot of dissipation by the bosonic bath: For weak enough JK, the Kondo effect is destroyed by dissipation. For strong JK, the spin is Kondo quenched. If there is a wide distribution of Kondo temperatures and e>0, then some spins will decouple and not be Kondo quenched Þ two fluid behavior Question: Will a positive e be self-consistently generated?
The leading order effect of the boson bath (instability analysis) Ignore self-consistency and calculate the spin response of the “bare” theory (limit of arbitrarily weak RKKY) Thus, e0 > 0 (sub-Ohmic dissipation of spins) if a < 2. We saw that: For strong enough disorder, the “bare” theory leads to a sub-Ohmic bath disorder W MIT W* insulator Fermi liquid “bare EGP” e0 > 0 a < 2 a < 1 Wc0 Two-fluid behavior
How will full self-consistency change this? Additive contributions from each fluid: Suppose the self-consistent bath goes like Decoupled spins: (Sengupta, `00; Zhu, Si, PRB `02; Zaránd, Demler, PRB ´02) Quenched spins: where n(e) is the “correlation time exponent” of the Bose-Fermi transition Clearly, edc>eK Þ decoupled spins dominate at low frequencies
Self-consistency Imposing self-consistency: Þ Sachdev-Ye spin liquid (PRL `93) Numerical results using large-N methods to solve the single-impurity problems: Marginal behavior over many decades disorder W MIT W* insulator Fermi liquid “bare EGP” e0 > 0 W1 NFL spin liquid Two-fluid behavior
Other consequences n(e) » e/2 + O(e2) »1/2 Þ Resistivity from the decoupled part: marginal Fermi liquid Low temperature spin-glass instability: Estimated from Large window with marginal behavior above Tg
Pr2Ir2O7 (S. Nakatsuji et al., preprint) Pirochlore lattice of Pr ions Very frustrated Large residual resistivity
Conclusions Clarification of the mechanism of the electronic Griffiths phase. With the inclusion of spin-spin interactions: For W>Wc Þ appearance of two fluids, Kondo quenched and spin liquid in a broad range of temperatures. Spin liquid Þ local c(w) is log-divergent. Kondo quenched Þ Power-law distribution of TK with a»0.5 (but c is non-singular, c~w0.5 ). Linear resistivity. Ultimately unstable towards spin-glass ordering at the lowest T.