2000
DOI: 10.1126/science.290.5491.501
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Electronic Structure of Solids with Competing Periodic Potentials

Abstract: When electrons are subject to a potential with two incommensurate periods, translational invariance is lost, and no periodic band structure is expected. However, model calculations based on nearly free one-dimensional electrons and experimental results from high-resolution photoemission spectroscopy on a quasi-one-dimensional material do show dispersing band states with signatures of both periodicities. Apparent band structures are generated by the nonuniform distribution of electronic spectral weight over the… Show more

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Cited by 186 publications
(169 citation statements)
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“…Such atomic displacements, in terms of a band Jahn-Teller effect, were suggested as a driving force for the transition. However, the key point is that, although the lattice distortion may shift the conduction band, the very small atomic displacements (≈ 0.02Å [3]) in 1T -TiSe 2 are expected to lead to a negligable spectral weight in the backfolded bands [20]. As an example, 1T -TaS 2 , another CDW compound known for very large atomic displacements [22] (of order > 0.1Å) introduces hardly detectable backfolding of spectral weight in ARPES.…”
Section: Pacs Numbersmentioning
confidence: 99%
See 1 more Smart Citation
“…Such atomic displacements, in terms of a band Jahn-Teller effect, were suggested as a driving force for the transition. However, the key point is that, although the lattice distortion may shift the conduction band, the very small atomic displacements (≈ 0.02Å [3]) in 1T -TiSe 2 are expected to lead to a negligable spectral weight in the backfolded bands [20]. As an example, 1T -TaS 2 , another CDW compound known for very large atomic displacements [22] (of order > 0.1Å) introduces hardly detectable backfolding of spectral weight in ARPES.…”
Section: Pacs Numbersmentioning
confidence: 99%
“…Such a large transfer of spectral weight into the backfolded bands is a very uncommon and striking feature. Indeed, in most compounds with competing potentials (CDW systems, vicinal surfaces,...), the backfolded bands carry an extremely small spectral weight [18,19,20]. In these systems the backfolding results mainly from the influence of the modified lattice on the electron gas, and the weight transfer is related to the strength of the new crystal potential component.…”
Section: Pacs Numbersmentioning
confidence: 99%
“…-10 momentum distribution of the spectral function in a standard band-folding or nesting scenario 26,27 . However, as it is presently unknown whether the HO state corresponds to a conventional density wave, and how the coherence factors should be calculated, a quantitative explanation of the observed distribution of spectral weight at E F lies beyond the scope of this work.…”
Section: Articlementioning
confidence: 99%
“…2 In these systems, such as charge-and spindensity waves (CDW and SDW), 3 Wigner cristals, superconductors in magnetic fields, 4 structurally incommensurate crystal phases, 5 the superstructure periodicities could be varied by external fields or temperature changes. The resulting metastable configurations can be reflected back onto the elastic properties and size of the underlying lattice, [3][4][5] though this question is still poorly understood.…”
mentioning
confidence: 99%