Mediums#
Non-Dispersive Medium#
Spatially uniform#
Dispersionless medium. |
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Perfect electrical conductor class. |
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Fully anisotropic medium including all 9 components of the permittivity and conductivity tensors. |
Spatially varying#
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Dispersive Mediums#
Spatially uniform#
A dispersive medium described by the pole-residue pair model. |
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A dispersive medium described by the Lorentz model. |
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A dispersive medium described by the Sellmeier model. |
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A dispersive medium described by the Drude model. |
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A dispersive medium described by the Debye model. |
Spatially varying#
A spatially varying dispersive medium described by the pole-residue pair model. |
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A spatially varying dispersive medium described by the Lorentz model. |
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A spatially varying dispersive medium described by the Sellmeier model. |
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A spatially varying dispersive medium described by the Drude model. |
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A spatially varying dispersive medium described by the Debye model. |
General Mediums (can be both dispersive and non-dispersive)#
Spatially uniform#
Diagonally anisotropic medium. |
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2D diagonally anisotropic medium. |
Spatially varying#
Diagonally anisotropic medium with spatially varying permittivity in each component. |
Medium Specifications (add properties to existing Medium)#
Nonlinear#
Abstract specification for adding nonlinearities to a medium. |
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Model for an instantaneous nonlinear chi3 susceptibility. |
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Model for Kerr nonlinearity which gives an intensity-dependent refractive index of the form \(n = n_0 + n_2 I\). |
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Model for two-photon absorption (TPA) nonlinearity which gives an intensity-dependent absorption of the form \(\alpha = \alpha_0 + \beta I\). |
Time Modulation#
Specification adding space-time modulation to the non-dispersive part of medium including relative permittivity at infinite frequency and electric conductivity. |
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Space-time modulation applied to a medium, adding on top of the time-independent part. |
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Class describing modulation with a harmonic time dependence. |
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The modulation profile with a user-supplied spatial distribution of amplitude and phase. |
Material Library#
- Material Library
- Silver (“Ag”)
- Aluminum (“Al”)
- Alumina (“Al2O3”)
- Aluminum Arsenide (“AlAs”)
- Aluminum Gallium Nitride (“AlGaN”)
- Aluminum Nitride (“AlN”)
- Aluminum Oxide (“AlxOy”)
- Amino Acid (“Aminoacid”)
- Amorphous Silicon (“aSi”)
- Gold (“Au”)
- Beryllium (“Be”)
- N-BK7 Borosilicate Glass (“BK7”)
- Calcium Fluoride (“CaF2”)
- Cellulose (“Cellulose”)
- Chromium (“Cr”)
- Crystalline Silicon (“cSi”)
- Copper (“Cu”)
- Fused Silica (“FusedSilica”)
- Gallium Arsenide (“GaAs”)
- Germanium (“Ge”)
- Germanium Oxide (“GeOx”)
- Graphene (“graphene”)
- tidy3d.Graphene
GrapheneGraphene.__init__()Graphene.mu_cGraphene.tempGraphene.gammaGraphene.scalingGraphene.include_interbandGraphene.interband_fit_freq_nodesGraphene.interband_fit_num_itersGraphene.mediumGraphene.intraband_drudeGraphene.interband_pole_residueGraphene.numerical_conductivity()Graphene.interband_conductivity()Graphene.__hash__()
- tidy3d.Graphene
- Water (“H2O”)
- Hafnium Oxide (“HfO2”)
- Hexamethyldisilazane, or Bis(trimethylsilyl)amine (“HMDS”)
- Indium Arsenide (“InAs”)
- Indium Phosphide (“InP”)
- Indium Tin Oxide (“ITO”)
- Magnesium Fluoride (“MgF2”)
- Magnesium Oxide (“MgO”)
- Molybdenum Disulfide (“MoS2”)
- Molybdenum Diselenide (“MoSe2”)
- Nickel (“Ni”)
- Palladium (“Pd”)
- Polyetherimide (“PEI”)
- Polyethylene Naphthalate (“PEN”)
- Polyethylene Terephthalate (“PET”)
- Poly(methyl Methacrylate) (“PMMA”)
- Polycarbonate (“Polycarbonate”)
- Polystyrene (“Polystyrene”)
- Platinum (“Pt”)
- Polytetrafluoroethylene, or Teflon (“PTFE”)
- Polyvinyl Chloride (“PVC”)
- Sapphire (“Sapphire”)
- Silicon Nitride (“Si3N4”)
- Silicon Carbide (“SiC”)
- Silicon Mononitride (“SiN”)
- Silicon Dioxide (“SiO2”)
- Silicon Oxynitride (“SiON”)
- Tantalum Pentoxide (“Ta2O5”)
- Titanium (“Ti”)
- Titanium Oxide (“TiOx”)
- Tungsten (“W”)
- Tungsten Disulfide (“WS2”)
- Tungsten Diselenide (“WSe2”)
- Yttrium Oxide (“Y2O3”)
- Yttrium Aluminium Garnet (“YAG”)
- Zirconium Oxide (“ZrO2”)