1. Photon and magnetic field controlled electron transport of a multiply-resonant photon-cavity double quantum dot system.
- Author
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Abdulkhalaq, Halo Anwar, Abdullah, Nzar Rauf, and Gudmundsson, Vidar
- Subjects
- *
MAGNETIC fields , *QUANTUM dots spectra , *MAGNETIC control , *PHOTONS , *MAGNETIC flux density , *ELECTRON transport - Abstract
We study electron transport through double quantum dots (DQD) coupled to a cavity with a single photon mode. The DQD is connected to two electron reservoirs, and the total system is under an external perpendicular magnetic field. The DQD system exhibits a complex multi-level energy spectrum. By varying the photon energy, several anti-crossings between photon dressed electron states of the DQD-cavity system are found at low strength of the magnetic field. The anti-crossings are identified as multiple Rabi resonances arising from the photon exchange between these states. As the results, a dip in the current is seen caused by the multiple Rabi resonances. By increasing the strength of the external magnetic field, a dislocation of the current dip to a lower photon energy is found and the current dip can be diminished. The interplay of the strength of the magnetic field and the geometry of the states the DQD system can weaken the multiple Rabi resonances in which the exchange of photon between the anti-crossings is decreased. We can therefore confirm that the electron transport behavior in the DQD-cavity system can be controlled by manipulating the external magnetic field and the photon cavity parameters. • Photon cavity induces anti-crossings in energy spectrum of double quantum dot. • Anti-crossings indicate Rabi-resonances. • Rabi-resonances decrease current in the double quantum dot. • External magnetic field can be used to diminish the effects of Rabi-resonances. [ABSTRACT FROM AUTHOR]
- Published
- 2022
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