# Effect of picosecond magnetic pulse on dynamics of electron's subbands   in semiconductor bilayer nanowire

**Authors:** T. Chwiej

arXiv: 1704.02150 · 2017-09-13

## TL;DR

This study demonstrates that a picosecond magnetic pulse can induce charge currents in a bilayer nanowire by dynamically tilting electron subbands through magnetic hybridization, with potential applications in ultrafast nanoelectronics.

## Contribution

It reveals a novel mechanism of charge current generation via magnetic hybridization and subband tilting in bilayer nanowires under ultrafast magnetic pulses, supported by time-dependent DFT calculations.

## Key findings

- Charge currents up to 0.6 μA can be generated.
- The effect depends on magnetic pulse duration and charge distribution.
- Subband tilting is driven by the magnetic field's time derivative.

## Abstract

We report on possibility of charge current generation in nanowire made of two tunnel coupled one-dimensional electron waveguides by means of single magnetic pulse lasting up to 20 ps. Existence of interlayer tunnel coupling plays a crucial role in the effect described here as it allows for hybridization of the wave functions localized in different layers which can be dynamically modified by applying a time changeable in-plane magnetic field. Results of time-dependent DFT calculations performed for a bilayer nanowire confining many electrons show that the effect of such magnetic hybridization relies on tilting of electrons' energy subbands, to the left or to the right, depending on a sign of time derivative of oscillating magnetic field due to the Faraday law. Consequently, the tilted subbands become a source of charge flow along the wire. Strength of such magneto-induced current oscillations may achieve even $0.6\mu\textrm{A}$ but it depends on duration of magnetic pulse as well as on charge density confined in nanowire which has to be unequally distributed between both transport layers to observe this effect.

## Full text

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## Figures

8 figures with captions in the complete paper: https://tomesphere.com/paper/1704.02150/full.md

## References

29 references — full list in the complete paper: https://tomesphere.com/paper/1704.02150/full.md

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Source: https://tomesphere.com/paper/1704.02150