From an experimentalist point of view, a model describing the "off-center" illumination of nanostructures is probably more realistic and useful. First, it is easier to perform experiments on ensembles of nanostructures, illuminated at normal incidence; here, the majority of the nanostructures will see a beam whose axis is displaced form their centers. Second, for single-structure experiments, an imprecise positioning of the beam's axis might introduce other effects. So, we wonder: how does the electronic excitation change when the beam is displaced?
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Figure 1: The TL beam axis is displaced with respect to
nanoparticle's center, in this case a quantum ring.
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\begin{equation}
\large J_\ell(q_r y) e^{i \ell \psi} = \sum_s J_{\ell+s}(q_r D) J_s(q_r r) e^{i s\phi}
\end{equation}
\large J_\ell(q_r y) e^{i \ell \psi} = \sum_s J_{\ell+s}(q_r D) J_s(q_r r) e^{i s\phi}
\end{equation}
A beam that looks from $\bf y$ like a single-$\ell$ beam, is seen from $\bf x$ as a superposition of single-$s$ beams. We want to express everything with respect to the $\bf x$ coordinate.
We have already seen how a single-$\ell$ beam affects a quantum dot or a quantum ring. A displaced beam will produce a superposition of the effects. The mathematical details of the model can be found in Ref. [1]. A pictorial representation of the interaction of an off-centered beam with a quantum ring is shown next.
We already described, in previous posts, the transitions shown in Fig. 2(a): it corresponds to a beam of topological charge $\ell=1$ impinging at normal incidence at the center of the quantum ring. When the same beam is displaced a distance $D$, the nanostructure "sees" a superposition of beams having different topological charge $s=0,1,2,..$. The electron in the valence band is promoted to a superposition of states in the conduction band, with relative weights that depend on $D$, the initial and final quantum number $m$ and the original topological charge $\ell$.
It is interesting to mention that, for a particular value of $q_r D$, the original transitions (valence $m=0 \rightarrow m=1$ conduction) does not happen.
Also, a real beam carrying no orbital angular momentum will also exhibit this behavior, due to the finite waist.
Reference
[1] G F Quinteiro, A O Lucero and P I Tamborenea, Electronic transitions in quantum dots and rings induced by inhomogeneous off-centered light beams, J. Phys.: Condens. Matter 22 (2010) 505802 (6pp).
We have already seen how a single-$\ell$ beam affects a quantum dot or a quantum ring. A displaced beam will produce a superposition of the effects. The mathematical details of the model can be found in Ref. [1]. A pictorial representation of the interaction of an off-centered beam with a quantum ring is shown next.
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| Figure 2: Valence to conduction band transitions in a quantum ring: (a) on-center $D=0$ irradiation, (b) off-center $D\neq0$ irradiation. |
It is interesting to mention that, for a particular value of $q_r D$, the original transitions (valence $m=0 \rightarrow m=1$ conduction) does not happen.
Also, a real beam carrying no orbital angular momentum will also exhibit this behavior, due to the finite waist.
Reference
[1] G F Quinteiro, A O Lucero and P I Tamborenea, Electronic transitions in quantum dots and rings induced by inhomogeneous off-centered light beams, J. Phys.: Condens. Matter 22 (2010) 505802 (6pp).
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