Joseph Maciejko scite author profile

We present direct experimental evidence for nonlocal transport in HgTe quantum wells in the quantum spin Hall regime, in the absence of any external magnetic field. The data conclusively show that the non-dissipative quantum transport occurs through edge channels, while the contacts lead to equilibration between the counter-propagating spin states at the edge. We show that the experimental data agree quantitatively with the theory of the quantum spin Hall effect.The quantum spin Hall (QSH) state (1, 2) is a topologically nontrivial state of matter which exists in the absence of any external magnetic field. It has a bulk energy gap but gapless helical edge states protected by time reversal symmetry. In the QSH regime, opposite spin states forming a Kramers doublet counter-propagate at the edge (3, 4). Recently, the QSH state has been theoretically predicted in HgTe quantum wells (5). There is a topological quantum phase transition at a critical thickness d c of the quantum well, separating the trivial insulator state for

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Kondo Effect in the Helical Edge Liquid of the Quantum Spin Hall State

Maciejko

et al. 2009

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Following the recent observation of the quantum spin Hall (QSH) effect in HgTe quantum wells, an important issue is to understand the effect of impurities on transport in the QSH regime. Using linear response and renormalization group methods, we calculate the edge conductance of a QSH insulator as a function of temperature in the presence of a magnetic impurity. At high temperatures, Kondo and/or two-particle scattering give rise to a logarithmic temperature dependence. At low temperatures, for weak Coulomb interactions in the edge liquid, the conductance is restored to unitarity with unusual power laws characteristic of a "local helical liquid," while for strong interactions, transport proceeds by weak tunneling through the impurity where only half an electron charge is transferred in each tunneling event.

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Spin polarization of the quantum spin Hall edge states

et al. 2012

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While the helical character of the edge channels responsible for charge transport in the quantum spin Hall regime of a two-dimensional topological insulator is by now well established, an experimental confirmation that the transport in the edge channels is spin-polarized is still outstanding. We report experiments on nanostructures fabricated from HgTe quantum wells with an inverted band structure, in which a split gate technique allows us to combine both quantum spin Hall and metallic spin Hall transport in a single device. In these devices, the quantum spin Hall effect can be used as a spin current injector and detector for the metallic spin Hall effect, and vice versa, allowing for an all-electrical detection of spin polarization.Comment: version 2: supplementary material with additional three figures added. In total 27 pages, 8 figure

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Joseph Maciejko

Nonlocal Transport in the Quantum Spin Hall State

Kondo Effect in the Helical Edge Liquid of the Quantum Spin Hall State

Spin polarization of the quantum spin Hall edge states

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