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Electronic effects in the Mo(001) surface reconstruction: Two-dimensional Fermi surfaces and nonadiabaticity

Journal Article · · Physical Review, B: Condensed Matter; (USA)
;  [1]
  1. Department of Physics, University of Oregon, Eugene, Oregon 97403 (US)
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The origins of the incommensurate reconstruction that Mo(001) undergoes when cooled below 220 K have been the subject of significant debate since its discovery. Much of the debate has centered on the relative importance of collective electronic phenomena in driving the reconstruction. We present here the two-dimensional Fermi surface for Mo(001), as measured using high-resolution angle-resolved photoemission spectroscopy. This Fermi surface consists of two structures: well-defined hole pockets about the {ital {bar M}} points in the surface Brillouin zone, and triangular-shaped regions midway along the {bar {Sigma}} line where an electron state came very close ({lt}0.2 eV) to {ital E}{sub {ital F}}. These regions can be considered as Fermi-surface crossings for the purposes of coupling to surface vibrations, and thus for playing a role in driving the reconstruction. The Fermi surface is shown to support a modified version of the charge-density-wave model for the reconstruction, with the incommensurate reconstruction being pinned by nested Fermi vectors along {bar {Sigma}}. We discuss the role of nonadiabatic phenomena in this reconstruction, show that the electronic structure predicts that such phenomena should occur, and provide an experimental basis for the inclusion of strong electron-phonon coupling in the charge-density-wave model of the reconstruction. Finally, our results for Mo(001) are compared with our earlier results for the two-dimensional Fermi surface of W(001), and we conclude that for both surfaces a combination of Fermi-surface instabilities and strong nonadiabatic effects is the most probable driving mechanism for the surface reconstructions.

DOE Contract Number:
FG06-86ER45275
OSTI ID:
5765264
Journal Information:
Physical Review, B: Condensed Matter; (USA), Journal Name: Physical Review, B: Condensed Matter; (USA) Vol. 43:5; ISSN 0163-1829; ISSN PRBMD
Country of Publication:
United States
Language:
English

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Related Subjects

36 MATERIALS SCIENCE
360102* -- Metals & Alloys-- Structure & Phase Studies
BREMSSTRAHLUNG
COOLING
CRYSTAL FACES
ELECTROMAGNETIC RADIATION
ELECTRON SPECTROSCOPY
ELECTRONIC STRUCTURE
ELEMENTS
ENERGY LEVELS
FERMI LEVEL
METALS
MOLYBDENUM
PHASE TRANSFORMATIONS
PHOTOELECTRON SPECTROSCOPY
RADIATIONS
SPECTROSCOPY
SYNCHROTRON RADIATION
TRANSITION ELEMENTS