Memory-function approach to the normal-state optical properties of the Bechgaard salt (TMTSF)_2PF_6
Ivan Kupcic
TL;DR
This paper develops a gauge-invariant optical conductivity model for quasi-one-dimensional systems like (TMTSF)_2PF_6, explaining insulating and metallic states and matching experimental data on correlation gaps and charge-density-wave behavior.
Contribution
It introduces a novel two-component optical conductivity model incorporating correlation gaps, applied to (TMTSF)_2PF_6, linking theoretical predictions with experimental observations.
Findings
The model accurately describes the optical response in insulating and metallic states.
Estimated band parameters align with previous experimental and theoretical results.
Evidence of a correlation gap opening in the charge excitation spectrum.
Abstract
The gauge invariant, two-component optical conductivity model, with a correlation gap structure related to the umklapp scattering processes, is applied to the quasi-one-dimensional electronic systems and compared to the recent measurements on the Bechgaard salt (TMTSF)_2PF_6. The optical response of both the insulating and metallic state is found for the half-filled conduction band, depending on the ratio between the correlation energy scale 2 \Delta^0_2 and the transfer integral in the direction perpendicular to the conducting chains, t_{{\rm b}'}. The estimated value 2 \Delta^0_2/t_{{\rm b}'} agrees reasonably well with the previous experimental and theoretical conclusions. Parallel to the chains the thermally activated conduction electrons in the insulating state are found to exhibit an universal behaviour, accounting for the observed single-particle optical conductivity of the…
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