Abstract
Nanophotonic devices manipulating light for high-speed computing are a counterpart of speed-limited electronic circuits. Although plasmonic circuits are a promising platform for subwavelength miniaturization, the logic-operation principle is still limited to mimicking those of photonic waveguides using phase shifts, polarization, interference, and resonance. Meanwhile, reconfigurable interconversion between exciton and plasmon engender emerging applications like exciton transistors and multiplexers, exciton amplifiers, chiral valleytronics, and nonlinear excitonics. Here, we propose optical logic principles realized by exciton-plasmon interconversion in Ag-nanowires (NW) overlapped on transition metal dichalcogenides (TMDs) monolayers. Excitons generated from TMDs couple to the Ag-NW plasmons, eventually collected as output signals at the Ag-NW end. Using two lasers, we demonstrate AND gate by modulating single excitons in Ag-NW on MoS2 and a half-adder by modulating dual excitons in lateral WSe2 and WS2. Moreover, a 4-to-2 binary encoder is realized in partially overlapped MoSe2 and MoS2 using four-terminal laser inputs. Our results represent great advances in communication processing for optical photonics integrable with subwavelength architectures.
Highlights
Hybridization methods of metallic NWs with excitonic quantum emitters, such as quantum dots and two-dimensional (2D) semiconductors have been widely investigated to modulate light signals in plasmonic waveguides[9,10,11,12,13,14,15,16]
When the green laser is irradiated in the middle part of Ag-NW, the laser light cannot be coupled to surface plasmon polaritons (SPPs), because the momentum compensation for longitudinal direction between SPP and incident light is not available at the midsection of NW
We have proposed a concept of logic principles for plasmonic waveguides via an optical operation at room temperature
Summary
Hybridization methods of metallic NWs with excitonic quantum emitters, such as quantum dots and two-dimensional (2D) semiconductors have been widely investigated to modulate light signals in plasmonic waveguides[9,10,11,12,13,14,15,16]. Ag-NWs hybridized with TMDs enable reconfigurable interconversion of exciton-to-plasmon and/or plasmon-to-exciton for optical communications[9,10]. We propose optical logic principles using plasmon-exciton interconversions in several architectures constructed by overlapping Ag-NWs on monolayer TMDs. For modulating exciton signals, two external lasers are utilized for simplified device structures. Smaller laser X power shows a larger on/off ratio. This originates from a smaller off-state level when small laser X power is applied
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