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    Journals >Laser & Optoelectronics Progress >Volume 58 >Issue 7 >Page 0723003 > Article
    • Laser & Optoelectronics Progress
    • Vol. 58, Issue 7, 0723003 (2021)
    Two Processing Methods of Graphene in Finite Element Calculation
    Yongzhe Zhao1, Da Teng1、*, Yuncheng Wang1, and Kai Wang2、**
    Author Affiliations
  • 1College of Physics and Electronic Engineering, Zhengzhou Normal University, Zhengzhou , Henan 450044, China
  • 2Key Laboratory of Infrared Imaging Materials and Detectors, Shanghai Institute of Technical Physics, Chinese Academy of Sciences, Shanghai 200083, China
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    DOI: 10.3788/LOP202158.0723003 Cite this Article Set citation alerts
    Yongzhe Zhao, Da Teng, Yuncheng Wang, Kai Wang. Two Processing Methods of Graphene in Finite Element Calculation[J]. Laser & Optoelectronics Progress, 2021, 58(7): 0723003 Copy Citation Text show less
    xoy cross-sections of two kinds of graphene waveguides. (a) Planar graphene dielectric structure; (b) curved graphene dielectric structure
    Fig. 1. xoy cross-sections of two kinds of graphene waveguides. (a) Planar graphene dielectric structure; (b) curved graphene dielectric structure
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    Distribution of fundamental mode field in planar graphene dielectric structure. (a) Field distribution of surface current method; (b) field distribution of thin-layer method; (c) one-dimensional field distribution curves
    Fig. 2. Distribution of fundamental mode field in planar graphene dielectric structure. (a) Field distribution of surface current method; (b) field distribution of thin-layer method; (c) one-dimensional field distribution curves
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    Performance curves of planar graphene dielectric structures under different f0 values. (a) Real part; (b) imaginary part; (c) relative deviation
    Fig. 3. Performance curves of planar graphene dielectric structures under different f0 values. (a) Real part; (b) imaginary part; (c) relative deviation
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    Performance curves of planar graphene dielectric structures under different μc values. (a) Real part; (b) imaginary part; (c) relative deviation
    Fig. 4. Performance curves of planar graphene dielectric structures under different μc values. (a) Real part; (b) imaginary part; (c) relative deviation
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    Distribution of fundamental mode fields in curved graphene dielectric structure. (a) Field distribution of surface current method; (b) field distribution of thin-layer method; (c) one-dimensional field distribution curves
    Fig. 5. Distribution of fundamental mode fields in curved graphene dielectric structure. (a) Field distribution of surface current method; (b) field distribution of thin-layer method; (c) one-dimensional field distribution curves
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    Performance curves of curved graphene dielectric structures under different f0 values. (a) Real part; (b) imaginary part; (c) relative deviation
    Fig. 6. Performance curves of curved graphene dielectric structures under different f0 values. (a) Real part; (b) imaginary part; (c) relative deviation
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    Performance curves of curved graphene dielectric structures at different R values. (a) Real part; (b) imaginary part; (c) relative deviation
    Fig. 7. Performance curves of curved graphene dielectric structures at different R values. (a) Real part; (b) imaginary part; (c) relative deviation
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    Performance curves of curved graphene dielectric structures at different μc values. (a) Real part; (b) imaginary part; (c) relative deviation
    Fig. 8. Performance curves of curved graphene dielectric structures at different μc values. (a) Real part; (b) imaginary part; (c) relative deviation
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    Yongzhe Zhao, Da Teng, Yuncheng Wang, Kai Wang. Two Processing Methods of Graphene in Finite Element Calculation[J]. Laser & Optoelectronics Progress, 2021, 58(7): 0723003
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