Johan Ekström scite author profile

Topologically protected qubits based on nanostructures hosting Majorana bound states (MBSs) hold great promise for fault-tolerant quantum computing. We study the transport properties of nanowire networks hosting MBSs with a focus on the effects of the charging energy and the overlap between neighboring MBSs in short mesoscopic samples. In particular, we investigate structures hosting four MBSs such as T junctions and Majorana boxes. Using a master equation in the Markovian approximation, we discuss the leading transport processes mediated by the MBSs. Single-electron tunneling and processes involving creation and annihilation of Cooper pairs dominate in the sequential-tunneling limit. In the cotunneling regime the charge in the MBSs is fixed and transport is governed by transitions via virtual intermediate states. Our results show that four-terminal measurements in the T junction and Majorana box geometries can be useful tools for the characterization of the properties of MBSs with finite overlaps and charging energy.

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Electron hydrodynamics of two-dimensional anomalous Hall materials

Hasdeo

Ekström

Idrisov

et al. 2021

Phys. Rev. B

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Kerr and Faraday rotations in topological flat and dispersive band structures

et al. 2022

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Integer quantum Hall (IQH) states and quantum anomalous Hall (QAH) states show the same static (dc) response but distinct dynamical (ac) response. In particular, the ac anomalous Hall conductivity profile σyx(ω) is sensitive to the band shape of QAH states. For example, dispersive QAH bands shows resonance profile without a sign change at the band gap while the IQH states shows the sign change resonance at the cyclotron energy. We argue by flattening the dispersive QAH bands, σyx(ω) should recover to that of flat Landau bands in IQH, thus it is necessary to know the origin of the sign change. Taking a topological lattice model with tunable bandwidth, we found that the origin of the sign change is not the band gap but the Van Hove singularity energy of the QAH bands. In the limit of small bandwidth, the flat QAH bands recovers σyx(ω) of the IQH Landau bands. Because of the Hall response, these topological bands exhibit giant polarization rotation and ellipticity in the reflected waves (Kerr effect) and rotation in the order of fine structure constant in the transmitted waves (Faraday effect) with profile resembles σyx(ω). Our results serve as a simple guide to optical characterization for topological flat bands.

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Kerr effect in tilted nodal loop semimetals

et al. 2021

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VHF-UHF propagation performance predictions for low altitude communication links operating over water

Ekström

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Johan Ekström

Transport properties of coupled Majorana bound states in the Coulomb blockade regime

Electron hydrodynamics of two-dimensional anomalous Hall materials

Kerr and Faraday rotations in topological flat and dispersive band structures

Kerr effect in tilted nodal loop semimetals

VHF-UHF propagation performance predictions for low altitude communication links operating over water

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