Preface
Acknowledgments
Author biography
1 Electromagnetics of graphene
1.1 Macroscopic electrodynamics
1.2 Constitutive relations
1.3 From the time domain to the frequency domain
1.4 Isotropic media
1.5 Conductivity and permittivity formulations
1.6 Constitutive relations of graphene
1.7 Ohmic losses
1.8 Kubo model for the surface conductivity
1.8.1 Intraband conductivity
1.8.2 Interband conductivity
1.8.3 Material dispersion
1.9 Decoupled equations
1.10 Boundary conditions
References
2 Single graphene sheet
2.1 Fresnel problem for a planar graphene sheet
2.1.1 s polarization
2.1.2 p polarization
2.1.3 Optics of a graphene monolayer
2.2 The finite thickness model
2.2.1 The problem for three regions
2.2.2 The 8 →0 limit
2.3 Graphene surface plasmon polaritons
2.3.1 Homogeneous problem for a graphene monolayer
2.3.2 Dispersion equations for graphene SPPs
2.3.3 Free-standing graphene
2.3.4 Solving dispersion relations
References
3 Layered structures
3.1 Multilayers as couplers
3.2 Film coupler
3.2.1 s polarization
3.2.2 p polarization
3.3 ATR excitation of graphene SPPs
3.3.1 s polarization
3.3.2 p polarization
3.4 Periodic multilayers
3.4.1 N layers: transfer matrix
3.4.2 N layers: reflectivity and transmissivity
3.4.3 1D photonic crystal
References
4 Graphene gratings
4.1 Boundary value problem
4.1.1 Field representation
4.1.2 Boundary conditions
4.1.3 Diffraction efficiencies and graphene absorption
4.2 Flat graphene gratings
4.2.1 s polarization
4.2.2 p polarization
4.3 Strip gratings
4.3.1 Removing strips from a graphene sheet
4.4 Localized graphene surface plasmons
4.4.1 Resonance condition
4.4.2 Near field
4.4.3 Numerical aspects
4.5 Propagating graphene surface plasmons
References
5 Graphene wires
5.1 2D graphene particles
5.2 Scattering problem
5.3 Scattered and absorbed power
5.4 Homogeneous problem
5.5 Connection between localized and propagating graphene surface
plasmons
5.6 Approximate analytical expressions for on
References
Appendix: Python scripts
编辑手记
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