1 / 14

Spin Incoherent Quantum Wires

Spin Incoherent Quantum Wires. Leon Balents Greg Fiete Karyn Le Hur. Frontiers of Science within Nanotechnology, BU August 2005. Atomic/molecular control many energy/length scales, individually controllable can access interesting physics with “emergent” or engineered separation of scales

fay
Download Presentation

Spin Incoherent Quantum Wires

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Spin Incoherent Quantum Wires Leon Balents Greg Fiete Karyn Le Hur Frontiers of Science within Nanotechnology, BU August 2005

  2. Atomic/molecular control many energy/length scales, individually controllable can access interesting physics with “emergent” or engineered separation of scales Small size = large Coulomb and large kinetic energy (» e2/r, ~2/mr2 ) Recurring theoretical problem: How to connect nano-structure to meso/macroscopic measuring devices? Nanoelectronics

  3. Quantum Wires Theory: 1DEG Dimensionless gas parameter rs: rs¿ 1 log rs rsÀ 1 Quasi-Wigner crystal regime Luttinger liquid theory E F “phonons” ZB»F rs1/2 k spin exchange

  4. Conductance Experiments Conductance (“0.7”) anomalies in quantum point contacts Thomas et al, 1996; widely reproduced since. • “plateau” better developed at intermediate temperatures • conductance moves toward G=0.5 (2 e^2/h) in longer constrictions Similar observations in gated nanotubes Biercuk et al, 2005

  5. QPC = Low density wire? “Spin incoherent regime” Matveev (2004) argues: G = e2/h (one orbital channel) with ideal metallic leads Picture J(x) coherent incoherent coherent kBT - “hot” spin excitations in leads too energetic to penetrate into wire Competing scenarios: Kondo (Meir et al), Ferromagnetism (various) - try to distinguish by other properties?

  6. Spectral Properties Cheianov+Zvonarev Greg Fiete+L.B. Introduce electron from outside via tunneling event A(k,) »2 »1/(4g)-1 k -kF kF -kF kF -kF kF 2kF Spin incoherent liquid Fermi liquid Luttinger liquid • Notable features: • No coherent single-particle propagation • Change kF! 2kF: spinless particles at total density • enhancement of local DOS: all spin states ¼ degenerate diverges for g>1/4

  7. How to get these results? Our calculation Cheianov+Zvonarev • Basic idea: Feynmann world-line path integral - J ¿ T: no crossings of world lines in “time”  = ~/kBT all particles between initial and final point must have same spin action too costly: negligible weight Can be evaluated by a simple Gaussian integral prob. of aligned spins Fermi statistics create/annihilate particle

  8. Some explicit formulae

  9. Momentum Resolved Tunneling Experiment: Auslaender et al., Science 2002 Theory: Carpentier et al., PRB 2002 (submitted 2000!) Tserkovnyak et al., PRL 2002 Zulicke & Governale, PRB 2002 E= eV k=eB/mc Steinberg et al, cond-mat/0506812 More recent experiments with one wire gated to low density: » A(k,¼ 0) k • interplay of disorder and interactions complicated Detailed analysis specific to these experiments: Fiete et al, cond-mat/0501684. (no L.B.!) 2 lobes

  10. Transport Properties • Suppose non-magnetic impurities/defects are introduced inside the spin incoherent wire. - General result: transport within the incoherent region is identical to that of a spinless Luttinger liquid with effective parameters G. Fiete, K. Le Hur, and LB (2005) geff = 2gc and kF,eff =2kF This can lead to interesting behavior with temperature e.g. Scattering from a single impurity with ½<gc<1 • increases with decreasing temperature for T¿ J • decreases with decreasing temperature for TÀ J Combination of coupling to coherent leads and defects is an open theoretical problem

  11. Charge Correlations • Low temperature: “Luttinger theorems”: - power-law charge correlations at Q=2kF (LSM, Affleck, Oshikawa) “usually” gc>1/3 : 2kF oscillations longest-range they must disappear when TÀ J may have implications for drag and impurity scattering when T passes through J ? Why 2k_F correlations at all in the Wigner picture? • Heisenberg chain has 1/r staggereddimer fluctuations - spin-phonon coupling leads to period 2 density oscillations 2/(4kF)

  12. Future Directions • Experiments to directly observe spin-incoherent physics? - Would like to see coherent spin transport “turn on/off” when T » J e.g very naïve geometry wire dot dot J À T: RKKY/2-impurity Kondo physics J ¿ T: no communication between spins of dots • Spin incoherent physics in ultracold fermions in 1d traps? - Measure hnki by expansion method hnki hnki T ¿ J TÀ J k 2kF k kF

  13. Theoretical Issues • Dynamics at long times: • 0<J ¿ T: all spin configurations equally likely at any instant, in equilibrium • spins frozen for t < 1/J. • what do spins do for t>1/J? • Diffusion? naively guess spin flip rate » J • integrability of Heisenberg chain: no diffusion? • impact on charge transport, spectral properties? • Equilibration time? • How long does it take to sample full set of spin configurations? • Hyperfine interaction with nuclei important?

  14. Thanks

More Related