[1] Gilarlue M M, Badri S H. Photonic crystal waveguide crossing based on transformation optics[J]. Optics Communications, 450, 308-315(2019).

[2] Headland D, Fujita M, Nagatsuma T. Bragg-mirror suppression for enhanced bandwidth in terahertz photonic crystal waveguides[J]. IEEE Journal of Selected Topics in Quantum Electronics, 26, 1-9(2019).

[3] Ruan W S, He X T, Zhao F L et al. Analysis of unidirectional coupling in topological valley photonic crystal waveguides[J]. Journal of Lightwave Technology, 39, 889-895(2020).

[4] Jindal P, jit Kaur H, Kaur A et al. Photonic crystal based biosensor-design and performance analysis for identification of various blood components[C], 1-5(2021).

[5] Fallahi V, Mohammadi M, Kordrostami Z et al. Design and optimization of an ultra-fast symmetrical 4×2 encoder based on 2D photonic crystal nano-resonators for integrated optical circuits[J]. Optical and Quantum Electronics, 53, 1-18(2021).

[6] Kriukova I S, Krivenkov V A, Samokhvalov P S et al. Weak coupling between light and matter in photonic crystals based on porous silicon responsible for the enhancement of fluorescence of quantum dots under two-photon excitation[J]. JETP Letters, 112, 537-542(2020).

[7] Li J F, Li C Y, Aroca R F. Plasmon-enhanced fluorescence spectroscopy[J]. Chemical Society Reviews, 46, 3962-3979(2017).

[8] Dadadzhanov D R, Gladskikh I A, Baranov M A et al. Self-organized plasmonic metasurfaces: The role of the Purcell effect in metal-enhanced chemiluminescence (MEC)[J]. Sensors and Actuators B Chemical, 333, 129453(2021).

[9] Lyasota A, Jarlov C, Rudra A et al. Limiting the spectral diffusion of nano-scale light emitters using the Purcell effect in a photonic-confined environment[J]. Scientific Reports, 9, 1-10(2019).

[10] Russell K J, Liu T L, Cui S et al. Large spontaneous emission enhancement in plasmonic nanocavities[J]. Nature Photonics, 6, 459-462(2012).

[11] Iorsh I, Poddubny A, Orlov A et al. Spontaneous emission enhancement in metal-dielectric metamaterials[J]. Physics Letters A, 376, 185-187(2012).

[12] Nikitin A Y, Guinea F, Garcia-Vidal F J et al. Surface plasmon enhanced absorption and suppressed transmissionin periodic arrays of graphene ribbons. Phys[J]. Rev. B: Condens. MatterMater. Phys, 85, 081405(2012).

[13] Jin Y, Feng J, Zhang X L et al. Surface-plasmon enhanced absorption in organic solar cells by employing a periodically corrugated metallic electrode[J]. Appl. Phys. Lett, 101, 163303-163308(2012).

[14] Lakowicz J R. Radiative decay engineering 3. surface plasmon-coupled directional emission[J]. Analytical Biochemistry, 324, 153-169(2004).

[15] Gryczynski I, Malicka J, Gryczynski Z et al. Surface plasmon-coupled emission with gold films[J]. Journal of Physical Chemistry B, 108, 12568-12574(2004).

[16] Yan S, Cheng Z, Hagedorn F L et al. Bandwidth-adaptable silicon photonic differentiator employing a slow light effect[J]. Optics Letters, 42, 1596-1599(2017).

[17] Elshahat S, Abood I, Khan K et al. Five-line photonic crystal waveguide for optical buffering and data interconnection of picosecond pulse[J]. Journal of Lightwave Technology, 37, 788-798(2019).

[18] Berenger J P. A perfectly matched layer for the absorption of electromagnetic waves[J]. Comput. Phys, 114, 185-200(1994).

[19] Goldberg M. stability criteria for finite difference approximations to parabolic systems[J]. Applied Numerical Mathematics, 33, 509-515(2000).

[20] Zhu Z, Brown T G. Full-vectorial finite-difference analysis of microstructured optical fibers[J]. Opt. Express, 10, 853-864(2002).