Twisted particles carry Orbital Angular Momentum (OAM), an important property
utilized to encode quantum information. The OAM of twisted photons can be trans-
ferred onto condensed matter systems in the form of twisted excitons. Numerical
solutions of the time-dependent Schr ̀ˆodinger equation for a 3-arm molecular chain are
used to demonstrate the manipulation of twisted excitons via an external magnetic
field. We present the first design for an OAM transistor in a quasi-1D system that
can be used to control the flow of OAM using the magnetic field. The underlying
mechanism is the interaction between OAM and the magnetic field which leads to a
orbit-resolved Bloch oscillation (ORBO). We present the semi-classical equations of
motion for this phenomenon in a one-dimensional system. Unlike classical Bloch oscil-
lation, an important effect in ultrafast electron dynamics, the magnet driven ORBO
is not limited by electrical breakdown and can easily be observed in natural solids.
Date of Award | Jun 2 2022 |
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Original language | English (US) |
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Awarding Institution | - Physical Sciences and Engineering
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Supervisor | Udo Schwingenschloegl (Supervisor) |
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- Twisted Particles
- Bloch Oscillation
- Information Transfer
- Orbital Angular Momentum