Presentation is loading. Please wait.

Presentation is loading. Please wait.

Ondas de densidade de carga em 1D: Hubbard vs. Luttinger? Thereza Paiva (UC-Davis) e Raimundo R dos Santos (UFRJ) Work supported by Brazilian agenciesand.

Published by Modified over 9 years ago

Similar presentations

Presentation on theme: "Ondas de densidade de carga em 1D: Hubbard vs. Luttinger? Thereza Paiva (UC-Davis) e Raimundo R dos Santos (UFRJ) Work supported by Brazilian agenciesand."— Presentation transcript:

1 Ondas de densidade de carga em 1D: Hubbard vs. Luttinger? Thereza Paiva (UC-Davis) e Raimundo R dos Santos (UFRJ) Work supported by Brazilian agenciesand

2 Outline Motivation Luttinger liquid description Hubbard model Hubbard superlattices Conclusions (References)

3 Motivation Strongly correlated electrons: interplay between charge and spin degrees of freedom determines magnetic and transport (including superconducting) properties

4 Quasi-2D example: high T c superconductors Striped phase?

5 Stripes in CuO 2 planes [from Kivelson et al., (‘99)] Direction of charge modulation

6 1D examples: organic conductors,… [from Gruner (‘94)] Chain direction SeC F P Spin density waves disappear for P ~ 6.0 kbar and triplet superconductivity sets in [Lee et al. (00)]

7 ... quantum wires, carbon nanotubes, etc.

8 Here: focus on charge distribution Charge-density waves

9 Well known example of CDW: the Peierls instability Electron-phonon coupling leads to a modulation of the charge distribution: Dynamics of collective modes     (x,t)  e.g., TTF-TCNQ, NbSe 3,... Here: interested only in effects of e - -e - interactions on CDW’s [from Gruner (88)]

10 Luttinger Liquid (LL) description Excitations: Fermi Liquid theory Fermi gasFermi liquid (interactions on) quasi-particles are fermions n  FF  FF n T=0 OK in 3D ? in 2D Breaks down in 1D (Peierls instability)  need new framework

11 The Luttinger model [Voit (‘94)] q  kF kF kF kF g2g2 kFkF kF kF q g4g4  Linear dispersion  Gapless excitations  Forward scattering (i.e. momentum transfer q << 2k F ):

12 Effect of dimensionality and spin-charge seperation: Let us inject an e - in 2 nd plane-wave state, |  2 , above Fermi surface g 4 only connects |  2  to |  1 , the 1 st plane wave state above Fermi surface Effective Hamiltonian in this subspace: Thus, g 4 irrelevant (RG: L   ) for d=3, but marginal for d=1

13 Diagonalizing H 4,eff yields u  = v F + g 4 /2   velocity of charge excitations u  = v F  g 4 /2   velocity of spin excitations u   u   spin-charge separation Solution of the Luttinger model Note low-T specific heat for fermions: C ~ T c.f., low-T specific heat for d-dimensional bosons with   k s : C ~ T d/s  linear for d=s=1 Quasi-particles are bosons  soluble via bosonization 

14 Charge-density correlation function    K F K F x x)x)k A xx xk A x K x nn 4 2 2/3 1 1 2 4cos( ln )2cos( )( )()0(    K  is a non-universal (interaction-dependent) exponent  2k F   n, where n is electron density 2k F dominates if 1  K   4K   K   1/3

15 Other measurable quantities – Specific heat: C =  T where 2  =  0 v F [u  -1 + u  -1 ], with  0 = 2  k B 2 / 3 v F – Spin susceptibility :  = 2 K  /  u  – Compressibility:  = 2 K  /  u  – Drude weight (DC conductivity): D = 2 u  K  Parametrization of theory (u , K  ) and (u , K  ) depend on the coupling constants g 2 & g 4

16 The Luttinger Liquid conjecture The LL is believed to provide the (gapless) low-energy phenomenology for all 1D metals

17 LL theory of single-wall metallic nanotubes: dielectric constant tube length tube radius  g ~ 0.2; c.f. g = 1 for Fermi gas LL behaviour observed through tunnelling experiments [see Egger et al. (‘00)]

18 The Hubbard model Simplest lattice model to include correlations :  Tight binding with one orbital per site  Coulomb repulsion: on-site only  Nearest neighbour hoppings only Bethe ansatz solution [Lieb & Wu (‘68)]  Ground state but not correlation functions

19 Connection with LL [Schulz(90)]: system size Calculated from Bethe ansatz solution  K  (n,U) K   1/2  2k F charge mode dominates over 4k F c.f. early Renormalization Group predictions [Sólyom(‘79)]

20 Quantum Monte Carlo (world-line) simulations [Hirsch & Scalapino (83,84)]:  first suggestions of 4k F charge mode dominating over 2k F as U increases  attributed to finite-temperature effects; should not prevail at lower temperatures Is it really so?

21 x  = M   NsNs M The space–imaginary-time lattice for QMC simulations The “minus-sign problem”: Sign of det ·det 

22 T  0: Quantum Monte Carlo (determinantal) simulations Charge susceptibility: As U increases, 4k F susceptibility still grows as T  0, while 2k F seems to stabilize. (N s  36 sites) Neither finite-size nor finite- temperature effects: simulations with   N s  96  N(4k F )  ln  n  1/6 [Paiva & dS (00a)]

23 T  0: Lanczos diagonalizations on finite-sized lattices is not …and is not a finite-size effect: cusps get sharper as N s increases As U increases the cusp moves towards 4k F... n  1/6

24 The same happens for other occupations n  1/3 n  1/2

25 Thus, 4k F charge mode indeed dominates over 2k F, at least for sufficiently large values of U. Agreement with LL description: 2k F amplitude A 1 (n,U)  0 for U  U  (n) Schematically: n 1 0 U 2kF2kF 4kF4kF U  (n)

26 Hubbard superlattices Model for layered systems [Paiva & dS (96)]: e.g., (thin) magnetic metallic multilayers U  0U  0 L0L0 LULU Interesting magnetic behaviour and metal-insulator transitions [Paiva & dS (‘98,’00)]; see also LL superlattices [Silva-Valencia et al. (‘00)]. With attractive interactions leads to coexistence between superconductivity and magnetism [Paiva (‘99)] Which is the dominant CDW mode?

27 Important parameter is # of electrons per cell: n eff  n (L 0  L U ) Define 2k F *   n eff  cusp is located at 4k F *

28 Conclusions For sufficiently large values of U, 4k F charge mode dominates over 2k F The LL description can only be made consistent if the amplitude of the 2k F mode vanishes For Hubbard superlattices the same results apply, with redefined n eff and k F * talk downloadable from http://www.if.ufrj.br/~rrds/rrds.html

29 References R Egger at al., cond-mat/0008008 G Grüner, Rev.Mod.Phys. 60, 1129 (1988) G Grüner, Rev.Mod.Phys. 66, 1 (1994) J E Hirsch and D J Scalapino, Phys.Rev.B 27, 7169 (1983) J E Hirsch and D J Scalapino, Phys.Rev.B 29, 5554 (1984) S Kivelson et al., cond-mat/9907228 I J Lee et al., cond-mat/0001332 E H Lieb and F Y Wu, Phys.Rev.Lett. 20, 1445 (1968) T Paiva, PhD thesis, UFF (1999) T Paiva and R R dos Santos, Phys.Rev.Lett. 76, 1126 (1996) T Paiva and R R dos Santos, Phys.Rev.B 58, 9607 (1998) T Paiva and R R dos Santos, Phys.Rev.B 61, 13480 (2000) T Paiva and R R dos Santos, Phys.Rev.B 62, 7004 (2000) H J Schulz, Phys.Rev.Lett. 64, 2831 (1990) J Silva-Valencia, E Miranda, and R R dos Santos, preprint (2000) J Sólyom, Adv.Phys. 28, 209 (1979) J Voit, Rep.Prog.Phys. 57, 977 (1994)

Download ppt "Ondas de densidade de carga em 1D: Hubbard vs. Luttinger? Thereza Paiva (UC-Davis) e Raimundo R dos Santos (UFRJ) Work supported by Brazilian agenciesand."

Similar presentations

Superconducting properties of carbon nanotubes

Superconducting properties of carbon nanotubes
Anderson localization: from single particle to many body problems.

Anderson localization: from single particle to many body problems.
Theory of the pairbreaking superconductor-metal transition in nanowires Talk online: sachdev.physics.harvard.edu Talk online: sachdev.physics.harvard.edu.

Theory of the pairbreaking superconductor-metal transition in nanowires Talk online: sachdev.physics.harvard.edu Talk online: sachdev.physics.harvard.edu.
From weak to strong correlation: A new renormalization group approach to strongly correlated Fermi liquids Alex Hewson, Khan Edwards, Daniel Crow, Imperial.

From weak to strong correlation: A new renormalization group approach to strongly correlated Fermi liquids Alex Hewson, Khan Edwards, Daniel Crow, Imperial.
Spin Incoherent Quantum Wires Leon Balents Greg Fiete Karyn Le Hur Frontiers of Science within Nanotechnology, BU August 2005.

Spin Incoherent Quantum Wires Leon Balents Greg Fiete Karyn Le Hur Frontiers of Science within Nanotechnology, BU August 2005.
Quantum Critical Behavior of Disordered Itinerant Ferromagnets D. Belitz – University of Oregon, USA T.R. Kirkpatrick – University of Maryland, USA M.T.

Quantum Critical Behavior of Disordered Itinerant Ferromagnets D. Belitz – University of Oregon, USA T.R. Kirkpatrick – University of Maryland, USA M.T.
High T c Superconductors & QED 3 theory of the cuprates Tami Pereg-Barnea

High T c Superconductors & QED 3 theory of the cuprates Tami Pereg-Barnea
Study of Collective Modes in Stripes by Means of RPA E. Kaneshita, M. Ichioka, K. Machida 1. Introduction 3. Collective excitations in stripes Stripes.

Study of Collective Modes in Stripes by Means of RPA E. Kaneshita, M. Ichioka, K. Machida 1. Introduction 3. Collective excitations in stripes Stripes.
Concepts in High Temperature Superconductivity

Concepts in High Temperature Superconductivity
D-wave superconductivity induced by short-range antiferromagnetic correlations in the Kondo lattice systems Guang-Ming Zhang Dept. of Physics, Tsinghua.

D-wave superconductivity induced by short-range antiferromagnetic correlations in the Kondo lattice systems Guang-Ming Zhang Dept. of Physics, Tsinghua.
Correlation functions in the Holstein-Hubbard model calculated with an improved algorithm for DMRG Masaki Tezuka, Ryotaro Arita and Hideo Aoki Dept. of.

Correlation functions in the Holstein-Hubbard model calculated with an improved algorithm for DMRG Masaki Tezuka, Ryotaro Arita and Hideo Aoki Dept. of.
Disordered two-dimensional superconductors Financial support: Collaborators: Felipe Mondaini (IF/UFRJ) [MSc, 2008] Gustavo Farias (IF/UFMT) [MSc, 2009]

Disordered two-dimensional superconductors Financial support: Collaborators: Felipe Mondaini (IF/UFRJ) [MSc, 2008] Gustavo Farias (IF/UFMT) [MSc, 2009]
Superconductivity in Zigzag CuO Chains

Superconductivity in Zigzag CuO Chains
Nonequilibrium dynamics of ultracold fermions Theoretical work: Mehrtash Babadi, David Pekker, Rajdeep Sensarma, Ehud Altman, Eugene Demler $$ NSF, MURI,

Nonequilibrium dynamics of ultracold fermions Theoretical work: Mehrtash Babadi, David Pekker, Rajdeep Sensarma, Ehud Altman, Eugene Demler $$ NSF, MURI,
Tunneling through a Luttinger dot R. Egger, Institut für Theoretische Physik Heinrich-Heine-Universität Düsseldorf M. Thorwart, S. Hügle, A.O. Gogolin.

Tunneling through a Luttinger dot R. Egger, Institut für Theoretische Physik Heinrich-Heine-Universität Düsseldorf M. Thorwart, S. Hügle, A.O. Gogolin.
Fermi-Liquid description of spin-charge separation & application to cuprates T.K. Ng (HKUST) Also: Ching Kit Chan & Wai Tak Tse (HKUST)

Fermi-Liquid description of spin-charge separation & application to cuprates T.K. Ng (HKUST) Also: Ching Kit Chan & Wai Tak Tse (HKUST)
Superconductivity: modelling impurities and coexistence with magnetic order Collaborators: Pedro R Bertussi (UFRJ) André L Malvezzi (UNESP/Bauru) F. Mondaini.

Superconductivity: modelling impurities and coexistence with magnetic order Collaborators: Pedro R Bertussi (UFRJ) André L Malvezzi (UNESP/Bauru) F. Mondaini.
Strongly Correlated Systems of Ultracold Atoms Theory work at CUA.

Strongly Correlated Systems of Ultracold Atoms Theory work at CUA.
5/2/2007Cohen Group Meeting1 Luttinger Liquids Kevin Chan Cohen Group Meeting May 2, 2007.

5/2/2007Cohen Group Meeting1 Luttinger Liquids Kevin Chan Cohen Group Meeting May 2, 2007.
Functional renormalization – concepts and prospects.

Functional renormalization – concepts and prospects.

Similar presentations

Ads by Google