Matija Karalic scite author profile

Quantum engineering requires controllable artificial systems with quantum coherence exceeding the device size and operation time. This can be achieved with geometrically confined low-dimensional electronic structures embedded within ultraclean materials, with prominent examples being artificial atoms (quantum dots) and quantum corrals (electronic cavities). Combining the two structures, we implement a mesoscopic coupled dot-cavity system in a high-mobility two-dimensional electron gas, and obtain an extended spin-singlet state in the regime of strong dot-cavity coupling. Engineering such extended quantum states presents a viable route for nonlocal spin coupling that is applicable for quantum information processing.

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Nonlocal transport via edge states in InAs/GaSb coupled quantum wells

Mueller

Pal

Karalic

et al. 2015

Phys. Rev. B

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Quantum spin Hall devices with edges much longer than several microns do not display ballistic transport: that is, their measured conductances are much less than e 2 /h per edge. We imaged edge currents in InAs/GaSb quantum wells with long edges and determined an effective edge resistance. Surprisingly, although the effective edge resistance is much greater than h/e 2 , it is independent of temperature up to 30 K within experimental resolution. Known candidate scattering mechanisms do not explain our observation of an effective edge resistance that is large yet temperature-independent.

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Experimental signatures of the inverted phase in InAs/GaSb coupled quantum wells

et al. 2016

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Transport measurements are performed on InAs/GaSb double quantum wells at zero and finite magnetic fields applied parallel and perpendicular to the quantum wells. We investigate a sample in the inverted regime where electrons and holes coexist, and compare it with another sample in the non-inverted semiconducting regime. Activated behavior in conjunction with a strong suppression of the resistance peak at the charge neutrality point in a parallel magnetic field attest to the topological hybridization gap between electron and hole bands in the inverted sample. We observe an unconventional Landau level spectrum with energy gaps modulated by the magnetic field applied perpendicular to the quantum wells. This is caused by strong spin-orbit interaction provided jointly by the InAs and the GaSb quantum wells.

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Electron-Hole Interference in an Inverted-Band Semiconductor Bilayer

et al. 2020

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Electron optics in the solid state promises new functionality in electronics through the possibility of realizing nano-and micrometer-sized interferometers, lenses, collimators, and beam splitters that manipulate electrons instead of light. Until now, however, such functionality has been demonstrated exclusively in one-dimensional devices, such as in nanotubes, and in graphene-based devices operating with p-n junctions. In this work, we describe a novel mechanism for realizing electron optics in two dimensions. By studying a two-dimensional Fabry-Perot interferometer based on a resonant cavity formed in an InAs/GaSb double quantum well using p-n junctions, we establish that electron-hole hybridization in band-inverted systems can facilitate coherent interference. With this discovery, we expand the field of electron optics in two dimensions to encompass materials that exhibit band inversion and hybridization.

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Gate-defined quantum point contact in an InSb two-dimensional electron gas

Lei

Lehner

Cheah

et al. 2021

Phys. Rev. Research

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Matija Karalic

Transport Spectroscopy of a Spin-Coherent Dot-Cavity System

Nonlocal transport via edge states in InAs/GaSb coupled quantum wells

Experimental signatures of the inverted phase in InAs/GaSb coupled quantum wells

Electron-Hole Interference in an Inverted-Band Semiconductor Bilayer

Gate-defined quantum point contact in an InSb two-dimensional electron gas

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