Lee, YY, Ho, WJ & Yeh, CW Fabrication of a silicon solar cell with >18% efficiency using spin-on-film processing for phosphorus and SiO diffusion2/TiO index graduated2 anti-reflective coating. Appl. Surf. Science. 35420–24 (2015).
Yakimov, A., Kirienko, V., Bloshkin, A., Dvurechenskii, A. & Utkin, D. Quantum dot-based mid-infrared photodetector enhanced by a metal-dielectric hybrid optical antenna. J.Phys. Appl. Phys. 53335105 (2020).
Magnusson, R. & Shin, D. Diffractive Optical Components. in Encyclopedia of Physical Sciences and Technology. 421–440. (2003).
Ota, Y. et al. Impact of Ge island size distributions as etching masks for anisotropic etching on the formation of antireflection structures. Jpn. J.Appl. Phys. 58045505 (2019).
Spinelli, P., Verschuuren, MA & Polman, A. Broadband omnidirectional antireflection coating based on sub-wavelength surface Mie resonators. Nat. Commmon. 3692 (2012).
Moitra, P. et al. Perfect reflectors made of full-scale dielectric metamaterials. ACS Photon. 2692–698 (2015).
Baryshnikova, KV, Petrov, MI, Babicheva, VE & Belov, PA Plasmonic antireflection coatings and spherical silicon nanoparticles. Science. representing 622136 (2016).
Visser, D., Basuvalingam, SB, Désières, Y. & Anand, S. Optical properties and fabrication of dielectric metasurfaces based on amorphous silicon nanodisk arrays. Opt. Express 275354–5367 (2019).
Shklyaev, AA & Tsarev, AV Broadband antireflective coatings made of resonant SiGe particles of submicron and micron size grown on Si substrates. IEEE Photon. J 132200212 (2021).
Kumar, R. & Ramakrishna, SA Enhanced infrared transmission through arrays of sub-wavelength holes in a thin gold film mounted with dielectric micro-domes. J.Phys. Appl. Phys. 51165104 (2018).
Anikin, K. et al. Localized surface plasmon resonance in arrays of gold nanoclusters on opaque substrates. Plasmonic 141527-1537 (2019).
Kuznetsov, AI, Miroshnichenko, AE, Fu, YH, Zhang, JB, and Luk’yanchuk, B. Magnetic light. Science. representing 2492 (2012).
Lepeshov, SI, Krasnok, AE, Belov, PA & Miroshnichenko, AE Hybrid nanophotonics. Phys. Usp. 611035-1050 (2018).
Utkin, DE, Anikin, KV, Veber, SL & Shklyaev, AA Dependence of light reflection from Mie germanium nanoresonators on their aspect ratio. Opt. Mater. 109110466 (2020).
Razmjooei, N., Ko, YH, Simlan, FA & Magnusson, R. Resonant reflection by arrays of microspheres with AR quenched Mie scattering. Opt. Exp. 2919183–19192 (2021).
Babicheva, VE & Evlyukhin, AB Resonant Lattice Kerker Effect in Metasurfaces with Electrical and Magnetic Optical Responses. Photon laser. Round. 111700132 (2017).
Wang, D. et al. Laser from finite arrays of plasmonic nanoparticles. ACS Photon. 7630–636 (2020).
Hakala, TK et al. Laser in dark and light modes of a finite size plasmon array. Nat. Commmon. 813687 (2017).
Danilov, A. et al. Ultra-narrow surface grating resonances in plasmonic metamaterial gratings for biosensing applications. Biosens. Bioelectron. 104102-112 (2018).
Altug, H., Oh, SH, Maier, SA & Homola, J. Advances and applications of nanophotonic biosensors. Nat. Nanotechnology. 175–16 (2022).
Ramezani, M., Lozano, G., Verschuuren, MA, and Gómez-Rivas, J. Modified emission of extended light-emitting layers by selective coupling to collective grating resonances. Phys. Rev. B 94125406 (2016).
Fan, X., Hao, Q., Qiu, T. & Chu, PK Improving LED performance through plasmonics-based strategies. J.Appl. Phys. 127040901 (2020).
Capers, JR, Boyes, SJ & Hibbins, AP Designing nonlocal collective responses of metasurfaces. Commmon. Phys. 4209 (2021).
Savelev, RS, Slobozhanyuk, AP, Miroshnichenko, AE, Kivshar, YS & Belov, PA Subwavelength waveguides composed of dielectric nanoparticles. Phys. Rev. B 89035435 (2014).
Ding, L. et al. Low-loss waveguiding and slow-light modes in sub-wavelength silicon-coupled Mie resonators. At the nanoscale 1221713–21718 (2020).
Bi, K. et al. Techniques for manufacturing all-dielectric metamaterials. Adv. Opt. Mater. 92001474 (2020).
Babicheva, VE & Moloney, JV Influence of lattice effect on electric and magnetic dipole resonance overlap in a disk lattice. Nanophotonics 71663-1668 (2018).
Utyushev, AD et al. Collective lattice resonances in fully dielectric nanostructures under oblique incidence. Photonics 724 (2020).
Xiong, L., Ding, H., Lu, Y. & Li, G. Extremely tight and actively tunable Mie surface lattice resonances in GeSbTe metasurfaces: study. Nanomaterials 12701 (2022).
Hopkins, B., Miroshnichenko, AE & Kivshar, YS Fully dielectric nanophotonic structures: exploring the magnetic component of light. in Recent Trends in Computational Photonics (eds. Agrawal, A., Benson, T., De La Rue, RM & Wurtz, GA). Kind. 10. (2017).
Staude, I. et al. Directional scattering adaptation through magnetic and electrical resonances in lower wavelength silicon nanodisks. ACS Nano 77824–7832 (2013).
Moitra, P., Slovick, BA, Yu, ZG, Krishnamurthy, S. & Valentine, J. Experimental demonstration of a perfect broadband all-dielectric metamaterial reflector. Appl. Phys. Lett. 104171102 (2014).
Here, J. et al. Near-infrared superabsorbent all-dielectric metasurface based on single-layer germanium nanostructures. Photon laser. Round. 121800076 (2018).
Zywietz, U. et al. Electromagnetic resonances of dimers of silicon nanoparticles in the visible. ACS Photon. 2913–920 (2015).
Yang, ZJ et al. Dielectric nanoresonators for manipulation of light. Phys. representing 7011–50 (2017).
Chong, KE et al. Observation of fano resonances in fully dielectric nanoparticle oligomers. Small ten1985–1990 (2014).
Utyushev, AD et al. Engineering novel high-Q tunable optical nanoparticle grating filters for a wide range of wavelengths. Opt. Exp. 281426-1438 (2020).
Ko, YH, Razmjooei, N., Hemmati, H. & Magnusson, R. Perfectly reflective guided-mode resonant photonic arrays possessing Mie modal memory. Opt. Exp. 2926971–26982 (2021).
Alaee, R., Filter, R., Lehr, D., Lederer, F. & Rockstuhl, C. A generalized Kerker condition for highly directive nanoantennas. Opt. Lett. 402645–2648 (2015).
Poborchii, V. et al. A photonic metasurface consisting of an array of lens-shaped SiGe Mie resonators formed on a (100) Si substrate by dewetting. Appl. Phys. Exp. ten125501 (2017).
Poborchii, V., Shklyaev, A., Bolotov, L. & Uchida, N. Nanoscale characterization of photonic metasurface consisting of lens-shaped SiGe Mie resonators formed on Si(100) substrate. J.Appl. Phys. 126123102 (2019).
Rsoft FullWave by SYNOPSYS. Edition 2020.09-1.
Taflove, A. & Hagnes, SC Computational electrodynamics: the time domain method of finite differences. 3rd ed. 1–997. (Artech, 2005).
Ed Palik, Handbook of Optical Constants of Solids. 1–999. (Academic, 1998).
Auguié, B., Bendaña, XM, Barnes, WL & de Abajo, FJG Diffractive gratings of gold nanoparticles close to an interface: critical role of the substrate. Phys. Rev. B 82155447 (2010).