High-Temperature Symmetry Breaking in the Electronic Band Structure of the Quasi-One-Dimensional Solid
- 23 October 2001
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review Letters
- Vol. 87 (19), 196403
- https://doi.org/10.1103/physrevlett.87.196403
Abstract
The electronic band structure of the Peierls compound has been explored for its symmetries with microspot synchrotron photoemission. The Fermi level crossings and deviations from one-dimensional behavior are identified. Density-functional calculations of the Fermi surfaces confirm the nesting conditions relevant for the two phase transitions. The instability along the chains with superstructure periodicity induces a backfolding of the electronic bands, and the Fermi level crossings appear suppressed. This broken symmetry is observed in the fluctuation regime at more than twice the critical temperature, where the correlation length is strongly reduced.
This publication has 16 references indexed in Scilit:
- Electronic Structure of Solids with Competing Periodic PotentialsScience, 2000
- Charge Density Wave Gap Formation ofDetected by Electron TunnelingPhysical Review Letters, 1999
- Effect of crystal-growth conditions on charge-density-wave pinning inPhysical Review B, 1992
- Comparison of the electronic structures of layered transition-metal trichalcogenides thallium triselenide, thallium trisulfide and niobium triselenideInorganic Chemistry, 1990
- Measurement of the Charge-Density-Wave Gap of NbSe3from Tunnel-Junction SpectraPhysical Review Letters, 1986
- Band Structure of NbSe3Journal of the Physics Society Japan, 1983
- Bands, bonds, and charge-density waves in the Nbfamily of compoundsPhysical Review B, 1979
- Charge-density waves in NbSe3 at 145K: crystal structures, X-ray and electron diffraction studiesJournal of Physics C: Solid State Physics, 1978
- Anomalous transport properties of a linear-chain metal: NbPhysical Review B, 1977
- An Exactly Soluble Model of a Many-Fermion SystemJournal of Mathematical Physics, 1963