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Robust integer and fractional helical modes in the quantum Hall effect


Electronic systems harboring one-dimensional helical modes, where spin and momentum are locked, have lately become an important field of their own. When coupled to a conventional superconductor, such systems are expected to manifest topological superconductivity; a unique phase hosting exotic Majorana zero modes. Even more interesting are fractional helical modes, yet to be observed, which open the route for realizing generalized parafermions. Possessing non-Abelian exchange statistics, these quasiparticles may serve as building blocks in topological quantum computing. Here, we present a new approach to form protected one-dimensional helical edge modes in the quantum Hall regime. The novel platform is based on a carefully designed double-quantum-well structure in a GaAs-based system hosting two electronic sub-bands; each tuned to the quantum Hall effect regime. By electrostatic gating of different areas of the structure, counter-propagating integer, as well as fractional, edge modes with opposite spins are formed. We demonstrate that, due to spin protection, these helical modes remain ballistic over large distances. In addition to the formation of helical modes, this platform can serve as a rich playground for artificial induction of compounded fractional edge modes, and for construction of edge-mode-based interferometers.

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Fig. 1: Schematic illustration of the concept of creating helical edge modes in a double-layer QHE system.
Fig. 2: MBE growth sequence, lithographic patterning and actual fan diagram.
Fig. 3: Tuning the structure to host integer helical modes.
Fig. 4: Spin-protected intermode tunnelling.
Fig. 5: Formation of fractional helical states.
Fig. 6: Contacting the helical edge modes directly.


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We acknowledge Johannes Nübler, Erez Berg, Yuval Oreg, Ady Stern,Yuval Gefen, Jinhong Park, Dmitri Feldman, Kyrylo Snizhko and Onder Gul for fruitful discussions. We thank Diana Mahalu for the e-beam processing and Vitaly Hanin for the help in the ALD process. M.H. acknowledges the partial support of the Israeli Science Foundation (ISF), the Minerva foundation, the US–Israel Bi-National Science Foundation (BSF), the European Research Council under the European Community’s Seventh Framework Program (FP7/2007–2013)/ERC Grant agreement 339070 and the German–Israeli Project Cooperation (DIP).

The data that support the plots within this paper and other findings of this study are available from the corresponding author upon reasonable request.

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Y.C. and Y.R. contributed equally to this work in heterostructure design, sample design, device fabrication, measurement set-up, data acquisition, data analysis and interpretation, and writing of the paper. D.B. contributed in heterostructure simulation, data analysis and interpretation, and writing of the paper. M.H. contributed in heterostructure design, sample design, data interpretation and writing of the paper. V.U. contributed in heterostructure design and molecular beam epitaxy growth.

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Correspondence to Moty Heiblum.

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Ronen, Y., Cohen, Y., Banitt, D. et al. Robust integer and fractional helical modes in the quantum Hall effect. Nature Phys 14, 411–416 (2018).

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