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Charge density wave

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A charge density wave (CDW) is an ordered quantum fluid of electrons in a linear chain compound or layered crystal. The electrons within a CDW form a standing wave pattern and sometimes collectively carry an electric current. The electrons in such a CDW, like those in a superconductor, can flow through a linear chain compound en masse, in a highly correlated fashion. Unlike a superconductor, however, the electric CDW current often flows in a jerky fashion, much like water dripping from a faucet, due to its electrostatic properties. In a CDW, the combined effects of pinning (due to impurities) and electrostatic interactions (due to the net electric charges of any CDW kinks) likely play critical roles in the CDW current's jerky behavior, as discussed in sections 4 & 5 below.

Most CDW's in metallic crystals form due to the wave-like nature of electrons – a manifestation of quantum mechanical wave–particle duality – causing the electronic charge density to become spatially modulated, i.e., to form periodic "bumps" in charge. This standing wave affects each electronic wave function, and is created by combining electron states, or wavefunctions, of opposite momenta. The effect is somewhat analogous to the standing wave in a guitar string, which can be viewed as the combination of two interfering, traveling waves moving in opposite directions (see interference (wave propagation)).

The CDW in electronic charge is accompanied by a periodic distortion – essentially a superlattice – of the atomic lattice.[1][2][3] The metallic crystals look like thin shiny ribbons (e.g., quasi-1-D NbSe3 crystals) or shiny flat sheets (e.g., quasi-2-D, 1T-TaS2 crystals). The CDW's existence was first predicted in the 1930s by Rudolf Peierls. He argued that a 1-D metal would be unstable to the formation of energy gaps at the Fermi wavevectors ±kF, which reduce the energies of the filled electronic states at ±kF as compared to their original Fermi energy EF.[4] The temperature below which such gaps form is known as the Peierls transition temperature, TP.

The electron spins are spatially modulated to form a standing spin wave in a spin density wave (SDW). A SDW can be viewed as two CDWs for the spin-up and spin-down subbands, whose charge modulations are 180° out-of-phase.

Fröhlich model of superconductivity

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In 1954, Herbert Fröhlich proposed a microscopic theory,[5] in which energy gaps at ±kF would form below a transition temperature as a result of the interaction between the electrons and phonons of wavevector Q=2kF. Conduction at high temperatures is metallic in a quasi-1-D conductor, whose Fermi surface consists of fairly flat sheets perpendicular to the chain direction at ±kF. The electrons near the Fermi surface couple strongly with the phonons of 'nesting' wave number Q = 2kF. The 2kF mode thus becomes softened as a result of the electron-phonon interaction.[6] The 2kF phonon mode frequency decreases with decreasing temperature, and finally goes to zero at the Peierls transition temperature. Since phonons are bosons, this mode becomes macroscopically occupied at lower temperatures, and is manifested by a static periodic lattice distortion. At the same time, an electronic CDW forms, and the Peierls gap opens up at ±kF. Below the Peierls transition temperature, a complete Peierls gap leads to thermally activated behavior in the conductivity due to normal uncondensed electrons.

However, a CDW whose wavelength is incommensurate with the underlying atomic lattice, i.e., where the CDW wavelength is not an integer multiple of the lattice constant, would have no preferred position, or phase φ, in its charge modulation ρ0 + ρ1cos[2kFx – φ]. Fröhlich thus proposed that the CDW could move and, moreover, that the Peierls gaps would be displaced in momentum space along with the entire Fermi sea, leading to an electric current proportional to dφ/dt. However, as discussed in subsequent sections, even an incommensurate CDW cannot move freely, but is pinned by impurities. Moreover, interaction with normal carriers leads to dissipative transport, unlike a superconductor.

CDWs in quasi-2-D layered materials

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Several quasi-2-D systems, including layered transition metal dichalcogenides,[7] undergo Peierls transitions to form quasi-2-D CDWs. These result from multiple nesting wavevectors coupling different flat regions of the Fermi surface.[8] The charge modulation can either form a honeycomb lattice with hexagonal symmetry or a checkerboard pattern. A concomitant periodic lattice displacement accompanies the CDW and has been directly observed in 1T-TaS2 using cryogenic electron microscopy.[9] In 2012, evidence for competing, incipient CDW phases were reported for layered cuprate high-temperature superconductors such as YBCO.[10][11][12]

CDW transport in linear chain compounds

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Early studies of quasi-1-D conductors were motivated by a proposal, in 1964, that certain types of polymer chain compounds could exhibit superconductivity with a high critical temperature Tc.[13] The theory was based on the idea that pairing of electrons in the BCS theory of superconductivity could be mediated by interactions of conducting electrons in one chain with nonconducting electrons in some side chains. (By contrast, electron pairing is mediated by phonons, or vibrating ions, in the BCS theory of conventional superconductors.) Since light electrons, instead of heavy ions, would lead to the formation of Cooper pairs, their characteristic frequency and, hence, energy scale and Tc would be enhanced. Organic materials, such as TTF-TCNQ were measured and studied theoretically in the 1970s.[14] These materials were found to undergo a metal-insulator, rather than superconducting, transition. It was eventually established that such experiments represented the first observations of the Peierls transition.

The first evidence for CDW transport in inorganic linear chain compounds, such as transition metal trichalcogenides, was reported in 1976 by Monceau et al.,[15] who observed enhanced electrical conduction at increased electric fields in NbSe3. The nonlinear contribution to the electrical conductivity σ vs. field E was fit to a Landau-Zener tunneling characteristic ~ exp[-E0/E] (see Landau–Zener formula), but it was soon realized that the characteristic Zener field E0 was far too small to represent Zener tunneling of normal electrons across the Peierls gap. Subsequent experiments[16] showed a sharp threshold electric field, as well as peaks in the noise spectrum (narrow band noise) whose fundamental frequency scales with the CDW current. These and other experiments (e.g.,[17]) confirm that the CDW collectively carries an electric current in a jerky fashion above the threshold field.

Classical models of CDW depinning

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Linear chain compounds exhibiting CDW transport have CDW wavelengths λcdw = π/kF incommensurate with (i.e., not an integer multiple of) the lattice constant. In such materials, pinning is due to impurities that break the translational symmetry of the CDW with respect to φ.[18] The simplest model treats the pinning as a sine-Gordon potential of the form u(φ) = u0[1 – cosφ], while the electric field tilts the periodic pinning potential until the phase can slide over the barrier above the classical depinning field. Known as the overdamped oscillator model, since it also models the damped CDW response to oscillatory (AC) electric fields, this picture accounts for the scaling of the narrow-band noise with CDW current above threshold.[19]

However, since impurities are randomly distributed throughout the crystal, a more realistic picture must allow for variations in optimum CDW phase φ with position – essentially a modified sine-Gordon picture with a disordered washboard potential. This is done in the Fukuyama-Lee-Rice (FLR) model,[20][21] in which the CDW minimizes its total energy by optimizing both the elastic strain energy due to spatial gradients in φ and the pinning energy. Two limits that emerge from FLR include weak pinning, typically from isoelectronic impurities, where the optimum phase is spread over many impurities and the depinning field scales as ni2 (ni being the impurity concentration) and strong pinning, where each impurity is strong enough to pin the CDW phase and the depinning field scales linearly with ni. Variations of this theme include numerical simulations that incorporate random distributions of impurities (random pinning model).[22]

Quantum models of CDW transport

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Early quantum models included a soliton pair creation model by Maki[23] and a proposal by John Bardeen that condensed CDW electrons tunnel coherently through a tiny pinning gap,[24] fixed at ±kF unlike the Peierls gap. Maki's theory lacked a sharp threshold field and Bardeen only gave a phenomenological interpretation of the threshold field.[25] However, a 1985 paper by Krive and Rozhavsky[26] pointed out that nucleated solitons and antisolitons of charge ±q generate an internal electric field E* proportional to q/ε. The electrostatic energy (1/2)ε[E ± E*]2 prevents soliton tunneling for applied fields E less than a threshold ET = E*/2 without violating energy conservation. Although this Coulomb blockade threshold can be much smaller than the classical depinning field, it shows the same scaling with impurity concentration since the CDW's polarizability and dielectric response ε vary inversely with pinning strength.[27]

Building on this picture, as well as a 2000 article on time-correlated soliton tunneling,[28] a more recent quantum model[29][30][31] proposes Josephson-like coupling (see Josephson effect) between complex order parameters associated with nucleated droplets of charged soliton dislocations on many parallel chains. Following Richard Feynman in The Feynman Lectures on Physics, Vol. III, Ch. 21, their time-evolution is described using the Schrödinger equation as an emergent classical equation. The narrow-band noise and related phenomena result from the periodic buildup of electrostatic charging energy and thus do not depend on the detailed shape of the washboard pinning potential. Both a soliton pair-creation threshold and a higher classical depinning field emerge from the model, which views the CDW as a sticky quantum fluid or deformable quantum solid with dislocations, a concept discussed by Philip Warren Anderson.[32]

Aharonov–Bohm quantum interference effects

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The first evidence for phenomena related to the Aharonov–Bohm effect in CDWs was reported in a 1997 paper,[33] which described experiments showing oscillations of period h/2e in CDW (not normal electron) conductance versus magnetic flux through columnar defects in NbSe3. Later experiments, including some reported in 2012,[34] show oscillations in CDW current versus magnetic flux, of dominant period h/2e, through TaS3 rings up to 85 μm in circumference above 77 K. This behavior is similar to that of the superconducting quantum interference device (see SQUID), lending credence to the idea that CDW electron transport is fundamentally quantum in nature (see quantum mechanics).

See also

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References

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Cited references

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  3. ^ B. Savitsky (2017). "Bending and breaking of stripes in a charge ordered manganite". Nature Communications. 8 (1): 1883. arXiv:1707.00221. Bibcode:2017NatCo...8.1883S. doi:10.1038/s41467-017-02156-1. PMC 5709367. PMID 29192204.
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  6. ^ John Bardeen (1990). "Superconductivity and other macroscopic quantum phenomena". Physics Today. 43 (12): 25–31. Bibcode:1990PhT....43l..25B. doi:10.1063/1.881218.
  7. ^ W. L. McMillan (1975). "Landau theory of charge-density waves in transition-metal dichalcogenides" (PDF). Physical Review B. 12 (4): 1187–1196. Bibcode:1975PhRvB..12.1187M. doi:10.1103/PhysRevB.12.1187.
  8. ^ A. A. Kordyuk (2015). "Pseudogap from ARPES experiment: Three gaps in cuprates and topological superconductivity (Review Article)". Low Temperature Physics. 41 (5): 319–341. arXiv:1501.04154. Bibcode:2015LTP....41..319K. doi:10.1063/1.4919371. S2CID 56392827.
  9. ^ R. Hovden; et al. (2016). "Atomic Lattice Disorder in Charge Density Wave Phases of Exfoliated Dichalcogenides (1T-TaS2)". Proc. Natl. Acad. Sci. U.S.A. 113 (41): 11420–11424. arXiv:1609.09486. Bibcode:2016PNAS..11311420H. doi:10.1073/pnas.1606044113. PMC 5068312. PMID 27681627.
  10. ^ T. Wu, H. Mayaffre, S. Krämer, M. Horvatić, C. Berthier, W. N. Hardy, R. Liang, D. A. Bonn, M.-H. Julien (2011). "Magnetic-field-induced charge-stripe order in the high-temperature superconductor YBa2Cu3Oy". Nature. 477 (7363): 191–194. arXiv:1109.2011. Bibcode:2011Natur.477..191W. doi:10.1038/nature10345. PMID 21901009. S2CID 4424890.{{cite journal}}: CS1 maint: multiple names: authors list (link)
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  12. ^ G. Ghiringhelli; M. Le Tacon; M. Minola; S. Blanco-Canosa; C. Mazzoli; N. B. Brookes; G. M. De Luca; A. Frano; D. G. Hawthorn; F. He; T. Loew; M. M. Sala; D. C. Peets; M. Salluzzo; E. Schierle; R. Sutarto; G. A. Sawatzky; E. Weschke; B. Keimer; L. Braicovich (2012). "Long-Range Incommensurate Charge Fluctuations in (Y,Nd)Ba2Cu3O6+x". Science. 337 (6096): 821–825. arXiv:1207.0915. Bibcode:2012Sci...337..821G. doi:10.1126/science.1223532. PMID 22798406. S2CID 30333430.
  13. ^ W. A. Little (1964). "Possibility of Synthesizing an Organic Superconductor". Physical Review. 134 (6A): A1416–A1424. Bibcode:1964PhRv..134.1416L. doi:10.1103/PhysRev.134.A1416.
  14. ^ P. W. Anderson; P. A. Lee; M. Saitoh (1973). "Remarks on giant conductivity in TTF-TCNQ". Solid State Communications. 13 (5): 595–598. Bibcode:1973SSCom..13..595A. doi:10.1016/S0038-1098(73)80020-1.
  15. ^ P. Monceau; N. P. Ong; A. M. Portis; A. Meerschaut; J. Rouxel (1976). "Electric Field Breakdown of Charge-Density-Wave—Induced Anomalies in NbSe3". Physical Review Letters. 37 (10): 602–606. Bibcode:1976PhRvL..37..602M. doi:10.1103/PhysRevLett.37.602.
  16. ^ R. M. Fleming; C. C. Grimes (1979). "Sliding-Mode Conductivity in NbSe3: Observation of a Threshold Electric Field and Conduction Noise". Physical Review Letters. 42 (21): 1423–1426. Bibcode:1979PhRvL..42.1423F. doi:10.1103/PhysRevLett.42.1423.
  17. ^ P. Monceau; J. Richard; M. Renard (1980). "Interference Effects of the Charge-Density-Wave Motion in NbSe3". Physical Review Letters. 45 (1): 43–46. Bibcode:1980PhRvL..45...43M. doi:10.1103/PhysRevLett.45.43.
  18. ^ George Gruner (1994). Density Waves in Solids. Addison-Wesley. ISBN 0-201-62654-3.
  19. ^ G. Grüner; A. Zawadowski; P. M. Chaikin (1981). "Nonlinear conductivity and noise due to charge-density-wave depinning in NbSe3". Physical Review Letters. 46 (7): 511–515. Bibcode:1981PhRvL..46..511G. doi:10.1103/PhysRevLett.46.511.
  20. ^ H. Fukuyama; P. A. Lee (1978). "Dynamics of the charge-density wave. I. Impurity pinning in a single chain". Physical Review B. 17 (2): 535–541. Bibcode:1978PhRvB..17..535F. doi:10.1103/PhysRevB.17.535.
  21. ^ P. A. Lee; T. M. Rice (1979). "Electric field depinning of charge density waves". Physical Review B. 19 (8): 3970–3980. Bibcode:1979PhRvB..19.3970L. doi:10.1103/PhysRevB.19.3970.
  22. ^ P. B. Littlewood (1986). "Sliding charge-density waves: A numerical study". Physical Review B. 33 (10): 6694–6708. Bibcode:1986PhRvB..33.6694L. doi:10.1103/PhysRevB.33.6694. PMID 9937991.
  23. ^ Kazumi Maki (1977). "Creation of soliton pairs by electric fields in charge-density—wave condensates". Physical Review Letters. 39 (1): 46–48. Bibcode:1977PhRvL..39...46M. doi:10.1103/PhysRevLett.39.46.
  24. ^ John Bardeen (1979). "Theory of non-ohmic conduction from charge-density waves in NbSe3". Physical Review Letters. 42 (22): 1498–1500. Bibcode:1979PhRvL..42.1498B. doi:10.1103/PhysRevLett.42.1498.
  25. ^ John Bardeen (1980). "Tunneling theory of charge-density-wave depinning". Physical Review Letters. 45 (24): 1978–1980. Bibcode:1980PhRvL..45.1978B. doi:10.1103/PhysRevLett.45.1978.
  26. ^ I. V. Krive; A. S. Rozhavsky (1985). "On the nature of threshold electric field in quasi-one-dimensional commensurate charge-density-waves". Solid State Communications. 55 (8): 691–694. Bibcode:1985SSCom..55..691K. doi:10.1016/0038-1098(85)90235-2.
  27. ^ G. Grüner (1988). "The dynamics of charge density waves". Reviews of Modern Physics. 60 (4): 1129–1181. Bibcode:1988RvMP...60.1129G. doi:10.1103/RevModPhys.60.1129.
  28. ^ J. H. Miller; C. Ordóñez; E. Prodan (2000). "Time-correlated soliton tunneling in charge and spin density waves". Physical Review Letters. 84 (7): 1555–1558. Bibcode:2000PhRvL..84.1555M. doi:10.1103/PhysRevLett.84.1555. PMID 11017566.
  29. ^ J.H. Miller, Jr.; A.I. Wijesinghe; Z. Tang; A.M. Guloy (2012). "Correlated quantum transport of density wave electrons". Physical Review Letters. 108 (3): 036404. arXiv:1109.4619. doi:10.1103/PhysRevLett.108.036404. PMC 11524153. PMID 22400766. S2CID 29510494.
  30. ^ J.H. Miller, Jr.; A.I. Wijesinghe; Z. Tang; A.M. Guloy (2013). "Coherent quantum transport of charge density waves". Physical Review B. 87 (11): 115127. arXiv:1212.3020. Bibcode:2013PhRvB..87k5127M. doi:10.1103/PhysRevB.87.115127. S2CID 119241570.
  31. ^ J.H. Miller, Jr.; A.I. Wijesinghe; Z. Tang; A.M. Guloy (2013). "Coherent quantum transport of charge density waves". Physical Review B. 87 (11): 115127. arXiv:1212.3020. Bibcode:2013PhRvB..87k5127M. doi:10.1103/PhysRevB.87.115127. S2CID 119241570.
  32. ^ Philip W. Anderson (1984). Basic Notions in Condensed Matter Physics. Benjamin/Cummings. ISBN 0-8053-0220-4.
  33. ^ Y. I. Latyshev; O. Laborde; P. Monceau; S. Klaumünzer (1997). "Aharonov-Bohm effect on charge density wave (CDW) moving through columnar defects in NbSe3". Physical Review Letters. 78 (5): 919–922. Bibcode:1997PhRvL..78..919L. doi:10.1103/PhysRevLett.78.919.
  34. ^ M. Tsubota; K. Inagaki; T. Matsuura; S. Tanda (2012). "Aharonov-Bohm effect in charge-density wave loops with inherent temporal current switching" (PDF). Europhysics Letters. 97 (5): 57011. arXiv:0906.5206. Bibcode:2012EL.....9757011T. doi:10.1209/0295-5075/97/57011. S2CID 119243023.

General references

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