Momentum-dependent electron-phonon coupling, enabled by Hubbard-corrected Fermi surface, is the leading driver of the charge density wave in quasi-1D ZrTe3.
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A microscopic Green's function theory models acoustic phonon self-energy from CDW fluctuations via local-intensity and texture channels, linking to soft-mode spectroscopy and anomalous thermal transport.
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Fermi surface geometry and momentum dependent electron-phonon coupling drive the charge density wave in quasi-1D ZrTe$3$
Momentum-dependent electron-phonon coupling, enabled by Hubbard-corrected Fermi surface, is the leading driver of the charge density wave in quasi-1D ZrTe3.
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Microscopic Theory of Acoustic Phonon Scattering by Charge-Density-Wave Fluctuations
A microscopic Green's function theory models acoustic phonon self-energy from CDW fluctuations via local-intensity and texture channels, linking to soft-mode spectroscopy and anomalous thermal transport.