[1] F GALVEZ, J DELVALLE, A GOMEZ et al. Plasmonic nanodevice with magnetic funcionalities:fabrication and characterization. Optical Materials Express, 6, 3086-3096(2016).

[2] X R SHEN, Y K WANG, Q S CHEN et al. Detuned square ring resonators for multiple plasmon-induced transparencies in metal-insulator-metal waveguide. Applied Physics Express, 8, 112201(2015).

[3] R ZAFAR, M SALIM. Enhanced figure of merit in Fano resonance-based plasmonic refractive index sensor. IEEE Sensors Journal, 15, 6313-6317(2015).

[4] U APARNA, H S MRUTHYUNJAYA, M SATHISH KUMAR. Plasmonic wavelength demultiplexer with mode conversion capabilities. Plasmonics, 13, 511-517(2018).

[5] N L KAZANSKIY, S N KHONINA, M A BUTT. Plasmonic sensors based on metal-insulator-metal waveguides for refractive index sensing applications: a brief review. Physica E:Low-dimensional Systems and Nanostructures, 113798(2020).

[6] S L WANG, Y H LIU, D Y ZHAO et al. Optofluidic Fano resonance photonic crystal refractometric sensors. Applied Physics Letters, 110, 091105(2017).

[7] H LU, X M LIU, D MAO et al. Plasmonic nanosensor based on Fano resonance in waveguide-coupled resonators. Optics Letters, 37, 3780-3782(2012).

[8] C WU, A B KHANIKAEV, R ADATO et al. Fano-resonant asymmetric metamaterials for ultrasensitive spectroscopy and identification of molecular monolayers. Nature Materials, 11, 69-75(2012).

[9] H LU, X LIU, L WANG et al. Ultrafast all-optical switching in nanoplasmonic waveguide with Kerr nonlinear resonator. Optics Express, 19, 2910-2915(2011).

[10] U F KEYSER. Enhancing nanopore sensing with DNA nanotechnology. Nature Nanotechnology, 11, 106-108(2016).

[11] S LAN, S P RODRIGUES, M TAGHINEJAD et al. Dark plasmonic modes in diatomic gratings for plasmoelectronics. Laser&Photonics Reviews, 11, 1600312(2017).

[12] Y HUANG, C MIN, S TAO et al. Design of compact Mach-Zehnder interferometer-based slow-light-enhanced plasmonic waveguide sensors. Journal of Lightwave Technology, 34, 2796-2803(2016).

[13] M CHEN, F FAN, L YANG et al. Tunable terahertz amplifier based on slow light edge mode in graphene plasmonic crystal. IEEE Journal of Quantum Electronics, 53, 1-6(2016).

[14] Z WEI, X LI, N ZHONG et al. Analogue electromagnetically induced transparency based on low-loss metamaterial and its application in nanosensor and slow-light device. Plasmonics, 12, 641-647(2017).

[15] S YAN, X ZHU, L H FRANDSEN et al. Slow-light-enhanced energy efficiency for graphene microheaters on silicon photonic crystal waveguides. Nature Communications, 8, 1-8(2017).

[16] M J AKRAM, F GHAFOOR, M M KHAN et al. Control of Fano resonances and slow light using Bose-Einstein condensates in a nanocavity. Physical Review A, 95, 023810(2017).

[17] Xiaowei LOU, Jinjiang CUI, Ningning DONG et al. Analysis of sharpness Fano resonance line based on eye-like resonator. Acta Photonica Sinica, 44, 0113002(2015).

[18] T CAO, C W WEI, R E SIMPSON et al. Fast tuning of double Fano resonance using a phase-change metamaterial under low power intensity. Scientific Reports, 4, 4463(2014).

[19] T CAO, L B MAO, Y M QIU et al. Fano resonance in asymmetric plasmonic nanostructure:separation of sub-10nm enantiomers. Advanced Optical Materials, 7, 1801172(2019).

[20] T CAO, Y M QIU. Lateral sorting of chiral nanoparticles using Fano-enhanced chiral force in visible region. Nanoscale, 10, 566-574(2018).

[21] J F CHEN, H YANG, Z Y FANG et al. Refractive index sensing based on multiple fano resonances in a split-ring cavity-coupled MIM waveguide. Photonics, 8, 472(2021).

[22] S YU, X PIAO, J HONG et al. Progress toward high-Q perfect absorption: a Fano antilaser. Physical Review A, 92, 011802(2015).

[23] N JANKOVIC, N CSELYUSZKA. Multiple Fano-like MIM plasmonic structure based on triangular resonator for refractive index sensing. Sensors, 18, 287-295(2018).

[24] Yanjun ZHANG, Huji WANG, Longtu ZHANG et al. Multi-Fano resonant sensing characteristics of MIM waveguide coupled with cloud like cavity. Acta Optica Sinica, 42, 0524002(2022).

[25] Yaping ZHAO, Guanmao ZHANG, Panpan REN et al. Dual Fano resonance characteristics of coupled semi-circular resonant cavity. Laser & Optoelectronics Progress, 57, 131301(2020).

[26] Yingqiu ZHANG, Xing LIU, Qiaohua WU et al. Study on the sensing and slow-light characteristics of Fano resonance in MIM waveguide with double baffles. Natural Science Journal of Harbin Normal University, 37, 30-36(2021).

[27] Xinchen YOU, Jianfei GUAN. Double Fano resonances based on coupled H-shaped cavity. Study on Optical Communications, 57-61(2021).

[28] Ying CHEN, Jian ZHOU, Zhixin DING et al. Analysis of formation and evolution of double Fano resonances in sub-wavelength dielectric grating/MDM waveguide/periodic photonic crystal. Acta Physica Sinica, 71, 034202(2022).

[29] F LIU, S YAN, L SHEN et al. A nanoscale sensor based on a toroidal cavity with a built-in elliptical ring structure for temperature sensing application. Nanomaterials, 12, 3396(2022).

[30] Yunping QI, Yingjun JIA, Ting ZHANG et al. Dynamically tunable refractive index sensor based on Fano resonance with metal-insulator-metal-graphene nanotube hybrid structure. Acta Physica Sinica, 71, 178101(2022).

[31] P B JOHNSON, R W CHRISTY. Optical constants of the noble metals. Physical Review B, 6, 4370(1972).

[32] S LI, Y WANG, R JIAO et al. Fano resonances based on multimode and degenerate mode interference in plasmonic resonator system. Optics Express, 25, 3525-3533(2017).

[33] S L QIU, Y P LI. Q-factor instability and its explanation in the staircased FDTD simulation of high-Q circular cavity. Journal of the Optical Society of America B, 26, 1664-1674(2009).

[34] S LI, Y WANG, R JIAO et al. Fano resonances based on multimode and degenerate mode interference in plasmonic resonator system. Optics Express, 25, 3525-3533(2017).

[35] T CAO, L ZHANG. Enhancement of Fano resonance in metal/dielectric/metal metamaterials at optical regime. Optics Express, 21, 19228-19239(2013).

[36] Z CHEN, J CHEN, L YU et al. Sharp trapped resonances by exciting the antisymmetric waveguide mode in a metal-insulator-metal resonator. Plasmonics, 10, 131-137(2015).