Abstract
The suite of highly confined polaritons
supported by two-dimensional
(2D) materials constitutes a versatile platform for nano-optics, offering
the means to channel light on deep-subwavelength scales. Graphene,
in particular, has attracted considerable interest due to its ability
to support long-lived plasmons that can be actively tuned via electrical
gating. While the excellent optoelectronic properties of graphene
are widely exploited in plasmonics, its mechanical flexibility remains
relatively underexplored in the same context. Here, we present a semianalytical
formalism to describe plasmons and other polaritons supported in waveguides
formed by bending a 2D material into a parabolic shape. Specifically,
for graphene parabolas, our theory reveals that the already large
field confinement associated with graphene plasmons can be substantially
increased by bending an otherwise flat graphene sheet into a parabola
shape, thereby forming a plasmonic waveguide without introducing potentially
lossy edge terminations via patterning. Further, we show that the
high field confinement associated with such channel polaritons in
2D parabolic waveguides can enhance the spontaneous emission rate
of a quantum emitter near the parabola vertex. Our findings apply
generally to 2D polaritons in atomically thin materials deposited
onto grooves or wedges prepared on a substrate or freely suspended
in a quasi-parabolic (catenary) shape. We envision that both the optoelectronic
and mechanical flexibility of 2D materials can be harnessed in tandem
to produce 2D channel polaritons with versatile properties that can
be applied to a wide range of nano-optics functionalities, including
subwavelength polaritonic circuitry and bright single-photon sources.
Original language | English |
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Journal | ACS Photonics |
Volume | 8 |
Issue number | 6 |
Pages (from-to) | 1840-1846 |
ISSN | 2330-4022 |
DOIs | |
Publication status | Published - 2021 |
Keywords
- Two-dimensional materials
- Parabolic waveguide
- Polaritons
- Channel plasmons
- Graphene plasmons
- Nanophotonics