Simulation and Analysis of Infrared Extinction Characteristics of ITO Nanorod Structures

Fang Chen; Rui Jiang; Zhaohui Zheng; Shaoying Ke; Jinrong Zhou; Guanzhou Liu; Zhiwei Huang

doi:10.3788/AOS221741

[1] Jin Y L. Gas sensitivity of ITO film based on SPR technology[D](2019).

[2] Lai S M, Huang Z W, Wang Y J et al. Simulation and analysis of local surface plasmon resonance of Ag nanostructures[J]. Laser＆Optoelectronics Progress, 55, 122601(2018).

[3] Yakupu X, Tuersun P. Rotation-symmetrical gold nanoparticles optimized for biological imaging[J]. Acta Optica Sinica, 41, 2329001(2021).

[4] Wu P P, Tuersun P, Abulaiti R et al. Optimization of light absorption and backscattering characteristics of Au-Ag alloy nanoshells[J]. Acta Optica Sinica, 41, 1129001(2021).

[5] Xiang S, Zhang X Y, Deng L G. Plasmon mode coupling relationship and optical properties of composite structure[J]. Laser＆Optoelectronics Progress, 58, 0924001(2021).

[6] Boltasseva A, Atwater H A. Low-loss plasmonic metamaterials[J]. Science, 331, 290-291(2011).

[7] West P R, Ishii S, Naik G V et al. Searching for better plasmonic materials[J]. Laser & Photonics Reviews, 4, 795-808(2010).

[8] Cai X Y. Preparation and surface plasmon properties of ITO films[D](2018).

[9] Kanehara M, Koike H, Yoshinaga T et al. Indium tin oxide nanoparticles with compositionally tunable surface plasmon resonance frequencies in the near-IR region[J]. Journal of the American Chemical Society, 131, 17736-17737(2009).

[10] Fang X, Mak C L, Zhang S Y et al. Pulsed laser deposited indium tin oxides as alternatives to noble metals in the near-infrared region[J]. Journal of Physics. Condensed Matter, 28, 224009(2016).

[11] Tuo Y F, Wu Y P, Huang M et al. The surface plasmon resonance absorption of indium tin oxide nanoparticles and its control[J]. Advanced Materials Research, 1118, 160-165(2015).

[12] Kim H, Gilmore C M, Piqué A et al. Electrical, optical, and structural properties of indium-tin-oxide thin films for organic light-emitting devices[J]. Journal of Applied Physics, 86, 6451-6461(1999).

[13] Tong L M, Xu H X. Surface plasmons: mechanisms, applications and perspectives[J]. Physics, 41, 582-588(2012).

[14] Wang Z W. Study on surface plasmonic properties and applications of doped n-type semiconductors[D](2020).

[15] Yee K E. Numerical solution of initial boundary value problems involving Maxwell's equations in isotropic media[J]. IEEE Transactions on Antennas and Propagation, 14, 302-307(1966).

[16] Chen X. Local surface plasmon effect of Al nanoparticles and its application in deep ultraviolet LED[D], 34(2013).

[17] Kim J, Naik G V, Emani N K et al. Plasmonic resonances in nanostructured transparent conducting oxide films[J]. IEEE Journal of Selected Topics in Quantum Electronics, 19, 4601907(2013).

[18] Askari H, Fallah H, Askari M et al. Electrical and optical properties of ITO thin films prepared by DC magnetron sputtering for low-emitting coatings[EB/OL]. https://arxiv.org/abs/1409.5293

[19] Song S M, Yang T L, Liu J J et al. Rapid thermal annealing of ITO films[J]. Applied Surface Science, 257, 7061-7064(2011).

[20] Link S, El-Sayed M A. Size and temperature dependence of the plasmon absorption of colloidal gold nanoparticles[J]. The Journal of Physical Chemistry B, 103, 4212-4217(1999).

[21] Jensen T, Kelly L, Lazarides A et al. Electrodynamics of noble metal nanoparticles and nanoparticle clusters[J]. Journal of Cluster Science, 10, 295-317(1999).

[22] Huang J X, Hu H, Wang Z W et al. Analysis of light-emission enhancement of low-efficiency quantum dots by plasmonic nano-particle[J]. Optics Express, 24, 8555-8573(2016).

[23] Peng H C. Study on the near-field enhancement and far-field properties of LSPR of Al nanoparticles[D], 44(2020).