Repulsion of Single-well Fundamental Edge Magnetoplasmons in Double Quantum Wells

Abstract

A microscopic treatment of fundamental edge magnetoplasmons (EMPs) along the edge of a double quantum well (DQW) is presented for strong magnetic fields, low temperatures, and total filling factor =2. It is valid for lateral confining potentials that Landau level (LL) flattening can be neglected. The cyclotron and Zeeman energies are assumed larger than the DQW energy splitting 2 +4T2, where is the splitting of the isolated wells and T the tunneling matrix element. %hen calculated unperturbed density profile is sharp at the edge. Using a random-phase approximation (RPA), which includes local and nonlocal contributions to the current density, it is shown that for negligible tunnel coupling 2T << the inter-well Coulomb coupling leads to two DQW fundamental EMPs which are strongly renormalized in comparison with the decoupled, single-well fundamental EMP. These DQW modes can be modified further upon varying the inter-well distance d, along the z axis, and/or the separation of the wells' edges y along the y axis. The charge profile of the fast and slow DQW mode varies, respectively, in an acoustic and optical manner along the y axis and is not smooth on the 0 scale. For strong tunneling 2T these DQW modes are essentially modified when is changed by applying a transverse electric field to the DQW.

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