[1] Zhang J C, Yu W X, Xiao F J et al. Tuning optical force of dielectric/metal core-shell placed above Au film[J]. Acta Physica Sinica, 69, 184206(2020).

[2] Zhang Q Q, Chen B, Xing L Z. Finite element analysis of photothermal properties of SiO2@Au core-shell nanoparticle[J]. Chinese Journal of Lasers, 48, 0907001(2021).

[3] Fan Y, Liu L, Zhang F. Exploiting lanthanide-doped upconversion nanoparticles with core/shell structures[J]. Nano Today, 25, 68-84(2019).

[4] Sun S, Rasskazov I L, Carney P S et al. Critical role of shell in enhanced fluorescence of metal-dielectric core-shell nanoparticles[J]. The Journal of Physical Chemistry C, 124, 13365-13373(2020).

[5] Zhang M T, Zheng G G, Wu H Y et al. Absorption characteristics of one-dimensional photonic crystal with graphene-based defect[J]. Chinese Journal of Quantum Electronics, 35, 326-331(2018).

[6] Meng W L, Wang Q Q, Shao J et al. Device performance dependence on photoactive composition in graphene-based hybrid solar cells[J]. Chinese Journal of Quantum Electronics, 39, 613-619(2022).

[7] Lawal A T. Graphene-based nano composites and their applications. A review[J]. Biosensors & Bioelectronics, 141, 111384(2019).

[8] Liu L L, Wang M, Jiao L P et al. Sensitivity enhancement of a graphene⁃barium titanate-based surface plasmon resonance biosensor with an Ag-Au bimetallic structure in the visible region[J]. Journal of the Optical Society of America B, 36, 1108-1116(2019).

[9] Sreejith S, Joseph J, Nguyen K T et al. Graphene oxide wrapping of gold-silica core-shell nanohybrids for photoacoustic signal generation and bimodal imaging[J]. ChemNanoMat, 1, 39-45(2015).

[10] Guo C Y, Wang D D, Mu C L. Progress on optical fiber sensors based on graphene/graphene oxide[J]. Laser & Optoelectronics Progress, 57, 150003(2020).

[11] Das S, Pandey D, Thomas J et al. The role of graphene and other 2D materials in solar photovoltaics[J]. Advanced Materials, 31, 1802722(2019).

[12] Feng J, Santamouris M. Numerical techniques for electromagnetic simulation of daytime radiative cooling: A review[J]. AIMS Materials Science, 6, 1049-1064(2019).

[13] Dakhlaoui H, Belhadj W, Wong B M. Quantum tunneling mechanisms in monolayer graphene modulated by multiple electrostatic barriers[J]. Results in Physics, 26, 104403(2021).

[14] Guo S J, Hu C X, Zhang H F. Unidirectional ultrabroadband and wide-angle absorption in graphene-embedded photonic crystals with the cascading structure comprising the Octonacci sequence[J]. Journal of the Optical Society of America B: Optical Physics, 37, 2678-2687(2020).

[15] Wu J J, Gao J X. Wideband absorption in one dimensional bilayer-graphene embedded photonic multilayer structure[J]. Superlattices and Microstructures, 140, 106437(2020).

[16] Rasskazov I L, Carney P S, Moroz A. STRATIFY: A comprehensive and versatile MATLAB code for a multilayered sphere[J]. OSA Continuum, 3, 2290-2306(2020).

[17] Carminati R, Greffet J J, Henkel C et al. Radiative and non-radiative decay of a single molecule close to a metallic nanoparticle[J]. Optics Communications, 261, 368-375(2006).

[18] Arruda T J, Bachelard R, Weiner J et al. Tunable Fano resonances in the decay rates of a pointlike emitter near a graphene-coated nanowire[J]. Physical Review B, 98, 245419(2018).

[19] Gingins M, Cuevas M, Depine R. Surface plasmon dispersion engineering for optimizing scattering, emission, and radiation properties on a graphene spherical device[J]. Applied Optics, 59, 4254-4262(2020).

[20] Gubin M Y, Prokhorov A V, Volkov V S et al. Controllable excitation of surface plasmon polaritons in graphene-based semiconductor quantum dot waveguides[J]. Annalen Der Physik, 533, 2100139(2021).

[21] Zhu J, Zhao S M. Improve the effective resonance light scattering of three-layered plasmonic Au@Dielectric@Ag bimetallic nanoshells[J]. Plasmonics, 17, 173-180(2022).

[22] Kumar P, Penta S, Mahapatra S P. Dielectric properties of graphene oxide synthesized by modified hummers' method from graphite powder[J]. Integrated Ferroelectrics, 202, 41-51(2019).