Plasmon exciton coupling enhances second order nonlinear response in borophene ZnO hybrid structures
Maximilian Black, Yaser Abdi, Prabhdeep Singh, Bharti Garg, Zahra Alavi + 5 more
TLDR
Borophene-ZnO hybrid structures leverage plasmon-exciton coupling to significantly enhance second-order nonlinear optical responses for frequency conversion.
Key contributions
- Borophene-ZnO heterostructures show an enhanced and resonant nonlinear optical response.
- Cathodoluminescence reveals a 2-order-of-magnitude enhancement at 400 nm and 800 nm.
- A clear second harmonic signal emerges with quadratic power dependence and strong resonance near 800 nm.
- Nonlinear plasmon-exciton coupling enables efficient hybrid pathways for frequency conversion.
Why it matters
This paper demonstrates a novel approach to overcome limitations of weak nonlinear optical processes in low-dimensional materials. By utilizing anisotropic plasmon-exciton hybridization, it opens new avenues for controlling and enhancing frequency conversion in nanoscale devices.
Original Abstract
Nonlinear optical processes in low dimensional materials are often weak or symmetry forbidden, limiting their use in nanoscale light sources and on chip frequency conversion. Here, we show that combining two weakly nonlinear systems, anisotropic borophene and excitonic zinc oxide, yields an enhanced and resonant nonlinear response. In borophene ZnO heterostructures, cathodoluminescence reveals a two orders of magnitude enhancement at 400 nm and 800 nm, due to an enhanced two photon absorption process. Under tunable near infrared excitation, a clear second harmonic signal emerges with quadratic power dependence and strong resonance near 800 nm. We attribute this to nonlinear plasmon exciton coupling, which reshapes the excitonic response and enables efficient hybrid pathways for frequency conversion. These results establish anisotropic plasmon exciton hybridization as a route to controlling nonlinear optical responses in low dimensional heterostructures.
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