Adaptive multi-spectral mimicking with 2D-material nanoresonator networks

IF 2 4区 物理与天体物理 Q3 OPTICS Journal of Optics Pub Date : 2024-05-16 DOI:10.1088/2040-8986/ad4722
Yujie Luo, Thomas Christensen and Ognjen Ilic
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Abstract

Active nanophotonic materials that can emulate and adapt between many different spectral profiles—with high fidelity and over a broad bandwidth—could have a far-reaching impact, but are challenging to design due to a high-dimensional and complex design space. Here, we show that a metamaterial network of coupled 2D-material nanoresonators in graphene can adaptively match multiple complex absorption spectra via a set of input voltages. To design such networks, we develop a semi-analytical auto-differentiable dipole-coupled model that allows scalable optimization of high-dimensional networks with many elements and voltage signals. As a demonstration of multi-spectral capability, we design a single network capable of mimicking four spectral targets resembling select gases (nitric oxide, nitrogen dioxide, methane, nitrous oxide) with very high fidelity ( ). Our results could impact the design of highly reconfigurable optical materials and platforms for applications in sensing, communication and display technology, and signature and thermal management.
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利用二维材料纳米震荡器网络进行自适应多光谱模拟
有源纳米光子材料能够在多种不同的光谱剖面之间进行仿真和适应--保真度高、带宽宽,可能会产生深远的影响,但由于存在高维和复杂的设计空间,其设计具有挑战性。在这里,我们展示了石墨烯中由耦合二维材料纳米共振器组成的超材料网络,可以通过一组输入电压自适应地匹配多种复杂的吸收光谱。为了设计这样的网络,我们开发了一种半分析自动微分偶极耦合模型,可以对具有许多元素和电压信号的高维网络进行可扩展的优化。作为多光谱能力的演示,我们设计了一个单一网络,能够以非常高的保真度()模拟与特定气体(一氧化氮、二氧化氮、甲烷、一氧化二氮)相似的四个光谱目标。我们的成果可能会影响高度可重构光学材料和平台的设计,从而应用于传感、通信和显示技术以及签名和热管理。
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来源期刊
CiteScore
4.50
自引率
4.80%
发文量
237
审稿时长
1.9 months
期刊介绍: Journal of Optics publishes new experimental and theoretical research across all areas of pure and applied optics, both modern and classical. Research areas are categorised as: Nanophotonics and plasmonics Metamaterials and structured photonic materials Quantum photonics Biophotonics Light-matter interactions Nonlinear and ultrafast optics Propagation, diffraction and scattering Optical communication Integrated optics Photovoltaics and energy harvesting We discourage incremental advances, purely numerical simulations without any validation, or research without a strong optics advance, e.g. computer algorithms applied to optical and imaging processes, equipment designs or material fabrication.
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