Mechanism and sensitivity of Fano resonance tuning in high-contrast gratings

Mechanism and tuning sensitivity of symmetry-protected resonances in high-contrast gratings

We develop a theory of refractive index tuning for symmetry-protected optical bound states (SP-BICs) in high-contrast gratings (HCGs). A compact analytical formula for tuning sensitivity is derived and verified numerically. We also discover a new type of SP-BIC in HCGs that has an accidental nature with a spectral singularity, which is explained in terms of hybridization and strong coupling among the odd- and even-symmetric waveguide-array modes. Our work elucidates the physics of tuning SP-BICs in HCGs and significantly simplifies their design and optimization for dynamic applications in light modulation, tunable filtering, and sensing.

Analysis of the water-soluble vitamins based on MIM waveguide structure and Fano resonance

Fano resonance (FR) is extremely sensitive to extremely small changes in the surrounding environment. We first propose an optical nano-refractive index sensor based on Fano resonance, which is applied to the identification of water-soluble vitamins B1, B5 and B6 and the measurement of the concentration of vitamin B1. The sensor can be used to rapidly identify pure vitamins B1, B5, and B6 at a concentration of 1 g/50 mL at 25 °C based on the relationship between the wavelength shift in the FR line spectrum and the refractive index. This work shows that the sensitivity of the sensor can reach 1327.5 nm/RIU, the sensor can be used to rapidly identify vitamins B1, B5, and B6 through changes in refractive index under certain conditions. Moreover, rapid calculation of vitamin B1 solution concentration is achieved based on the relationship between different concentrations of vitamin B1 solution and their corresponding refractive indexes and wavelength shifts in their FR line spectrums, which is an important step for the application of the designed MIM waveguide structures to the fields of biology, chemistry, and medicine.

Dielectric Properties of BaTiO3-Epoxy Nanocomposites in the Microwave Regime

We synthesized BaTiO₃–epoxy nanocomposites (particle size < 100 nm) with volume fractions up to 25 vol. %, whose high-frequency complex permittivity was characterized from 8.2 to 12.5 GHz. The maximum dielectric constant approaches 9.499 with an acceptable loss tangent of 0.113. The dielectric loss gradually saturates when the particle concentration is higher than 15 vol. %. This special feature is an important key to realizing high-k and low-loss nanocomposites. By comparing the theoretical predictions and the experimental data, four applicable effective-medium models are suggested. The retrieved dielectric constant (loss tangent) of 100-nm BaTiO₃ nanopowder is in the range of 50–90 (0.1–0.15) at 8.2–12.5 GHz, exhibiting weak frequency dispersion. Two multilayer microwave devices—total reflection and antireflection coatings—are designed based on the fabricated nanocomposites. Both devices show good performance and allow broadband operation.