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Trembling electrons cause conductance fluctuation

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 Added by Yu Iwasaki
 Publication date 2016
  fields Physics
and research's language is English




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The highly successful Dirac equation can predict peculiar effects such as Klein tunneling and the Zitterbewegung (German for trembling motion) of electrons. From the time it was first identified by Erwin Schrodinger, Zitterbewegung (ZB) has been considered a key to understanding relativistic quantum mechanics. However, observing the original ZB of electrons is too difficult, and instead various emulations using entity models have been proposed, producing several successes. Expectations are high regarding charge transports in semiconductors and graphene; however, very few reports have appeared on them. Here, we report that ZB has a surprisingly large effect on charge transports when we play flat pinball with such trembling electrons in a semiconductor nanostructure. The stage here is a narrow strip of InAs two-dimensional electron gas with a strong Rashba spin-orbit coupling. Six quantum point contacts (QPCs) are attached to the strip as pinball pockets. The ZB appeared as a large reproducible conductance fluctuation versus in-plane magnetic fields in the transport between two QPCs. Numerical simulations successfully reproduced our experimental observations, certifying that ZB causes a new type of conductance fluctuation.



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154 - W. Zawadzki , T. M. Rusin 2008
Theory of trembling motion [Zitterbewegung (ZB)] of charge carriers in various narrow-gap materials is reviewed. Nearly free electrons in a periodic potential, InSb-type semiconductors, bilayer graphene, monolayer graphene and carbon nanotubes are considered. General features of ZB are emphasized. It is shown that, when the charge carriers are prepared in the form of Gaussian wave packets, the ZB has a transient character with the decay time of femtoseconds in graphene and picoseconds in nanotubes. Zitterbewegung of electrons in graphene in the presence of an external magnetic field is mentioned. A similarity of ZB in semiconductors to that of relativistic electrons in a vacuum is stressed. Possible ways of observing the trembling motion in solids are mentioned.
The relationship between the universal conductance fluctuation and the weak localization effect in monolayer graphene is investigated. By comparing experimental results with the predictions of the weak localization theory for graphene, we find that the ratio of the elastic intervalley scattering time to the inelastic dephasing time varies in accordance with the conductance fluctuation; this is a clear evidence connecting the universal conductance fluctuation with the weak localization effect. We also find a series of scattering lengths that are related to the phase shifts caused by magnetic flux by Fourier analysis.
75 - H. Hou , Y. Kozuka , Jun-Wei Liao 2019
Oxide heterostructures are versatile platforms with which to research and create novel functional nanostructures. We successfully develop one-dimensional (1D) quantum-wire devices using quantum point contacts on MgZnO/ZnO heterostructures and observe ballistic electron transport with conductance quantised in units of 2e^{2}/h. Using DC-bias and in-plane field measurements, we find that the g-factor is enhanced to around 6.8, more than three times the value in bulk ZnO. We show that the effective mass m^{*} increases as the electron density decreases, resulting from the strong electron-electron interactions. In this strongly interacting 1D system we study features matching the 0.7 conductance anomalies up to the fifth subband. This paper demonstrates that high-mobility oxide heterostructures such as this can provide good alternatives to conventional III-V semiconductors in spintronics and quantum computing as they do not have their unavoidable dephasing from nuclear spins. This paves a way for the development of qubits benefiting from the low defects of an undoped heterostructure together with the long spin lifetimes achievable in silicon.
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