Ren Ziheng, Hu Yuze, He Weibao, Wan Shun, Hu Siyang, Yu Zhongyi, Cheng Xiang'ai, Xu Zhongjie, Jiang Tian
College of Advanced Interdisciplinary Studies, National University of Defense Technology, Changsha 410073, China.
Institute for Quantum Science and Technology, College of Science, National University of Defense Technology, Changsha 410073, China.
ACS Nano. 2024 Aug 13;18(32):21211-21220. doi: 10.1021/acsnano.4c04565. Epub 2024 Jul 30.
In photonics, achieving high-quality () resonance is crucial for high-sensitivity devices used in applications, such as switching, sensing, and lasing. However, high- resonances are highly susceptible to internal losses of plasmonic devices, impeding their integration into broader systems across terahertz and visible light bands. Here, we overcome this challenge by proposing a low- plasmonic metasurface for ultrasensitive terahertz (THz) switching and sensing. Theoretically, we reveal an approach to constructing a low- resonator possessing high sensitivity to nonradiative losses. Leveraging this mechanism, we design a highly sensitive plasmonic metasurface induced by strong coupling between a quasi-bound state in the continuum and a dipole mode. By hybridizing with the germanium layer, the metadevice exhibits an ultralow pump threshold of 192 μJ/cm and an ultrafast switching cycle time of 7 ps. Furthermore, it also shows a high sensitivity of 224 GHz/RIU in refractive index sensing. The proposed paradigm of constructing low- and high-sensitivity photonic devices can be applied to biosensing, wide-band filters, and sensitive modulators.
在光子学中,实现高质量()共振对于诸如开关、传感和激光等应用中使用的高灵敏度器件至关重要。然而,高共振极易受到等离子体器件内部损耗的影响,阻碍了它们集成到跨越太赫兹和可见光波段的更广泛系统中。在此,我们通过提出一种用于超灵敏太赫兹(THz)开关和传感的低等离子体超表面来克服这一挑战。从理论上讲,我们揭示了一种构建对非辐射损耗具有高灵敏度的低共振器的方法。利用这一机制,我们设计了一种由连续统中的准束缚态与偶极模式之间的强耦合诱导的高灵敏度等离子体超表面。通过与锗层杂交,该超器件表现出192 μJ/cm的超低泵浦阈值和7 ps的超快开关周期时间。此外,它在折射率传感中还显示出224 GHz/RIU的高灵敏度。所提出的构建低灵敏度和高灵敏度光子器件的范例可应用于生物传感、宽带滤波器和灵敏调制器。
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