Theory of charge dynamics in bilayer electron system with long-range Coulomb interaction

Abstract

We perform a comprehensive study of charge excitations in a bilayer electron system in the presence of the long-range Coulomb interaction (LRC). Our major point is to derive formulae of the LRC that fully respect the bilayer lattice structure. This is an extension of the LRC obtained by Fetter in the electron-gas model 50 years ago and can now be applicable to any electron density. We then provide general formulae of the charge susceptibility in the random phase approximation and study them numerically. The charge ordering tendency is not found and instead we find two plasmon modes, w+ and w- modes. Our second major point is to elucidate their spectral weight distribution and the effect of electron tunneling between the layers. The spectral weight of the w+- modes does not have 2pi periodicity along the qzc direction. The w+ mode loses spectral weight at inplane momentum q||=(0,0) at qzc=2n pi with n being integer whereas the w- mode has no spectral weight at qzc=0 for any q|| but acquires sizable spectral weight at qzc=2n pi with n 0. Both w+- modes are gapped at q||=(0,0). When qzc is away from 2n pi, the w+- modes show striking behavior. When the intrabilayer hopping tz is relatively small (large), the w- (w+) mode becomes gapless at q||=(0,0) whereas the w+ (w-) mode retains the gap. However, when the interbilayer hopping integral tz' is taken into account, the gapless mode acquires a gap at q||=(0,0) and both w+- modes are gapped at any qzc. To highlight the special feature of the LRC, we also clarify a difference to the case of a short-range interaction. While the strong electron correlation effects are not included, the present theory captures available data of the charge excitations observed by resonant inelastic x-ray scattering for Y-based cuprate superconductors.

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