COMSOL Multiphysics^® 6.3 Release Highlights

Wave Optics Module Updates

For users of the Wave Optics Module, COMSOL Multiphysics^® version 6.3 simplifies modeling of periodic structures, introduces tools for calculating optical absorption, scattering, and extinction properties, and enhances wave absorption capabilities, allowing scattered waves to be absorbed in any specified direction. Learn more about these updates below.

New Periodic Structure Feature

The new Periodic Structure feature, available as a domain condition in the Electromagnetic Waves, Frequency Domain interface, simplifies the modeling of periodic structures. By adding this feature and selecting the excited port boundary, the necessary ports and periodic conditions are automatically set up. The feature includes settings similar to those used for Periodic port features. The following tutorial models demonstrate this feature:

The COMSOL Multiphysics UI showing the Model Builder with the Periodic Structure node highlighted, the corresponding Settings window, and an acousto-optic modulator model in the Graphics window.

The Periodic Structure feature by default adds all relevant features, such as ports and periodic conditions, as subnodes.

Cross Section Calculation Feature Added to the Electromagnetic Waves, Frequency Domain Interface

The Cross Section Calculation feature has been added to the Electromagnetic Waves, Frequency Domain interface for the scattered field formulation. It allows accurate calculation of scattering, absorption, and extinction cross sections when a plane wave is used as the setting for the Background electric field. The cross-section variables are accessible as global variables for subplot nodes in the Replace Expression menu in the Cross sections category. This feature is demonstrated in the Scatterer on Substrate and Optical Scattering off a Gold Nanosphere tutorial models.

The COMSOL Multiphysics UI showing the Model Builder with the Cross Section Calculation node highlighted, the corresponding Settings window, and a substrate model in the Graphics window.

To calculate the cross-section variables of a scatterer, the Cross Section Calculation feature is applied to the scatterer.

Matched Boundary Condition Added to the Electromagnetic Waves, Frequency Domain Interface

The Matched Boundary Condition feature has been added to the Electromagnetic Waves, Frequency Domain interface, making boundaries transparent to waves with a known scattered direction, minimizing reflections. For scenarios with an incident field, a Reference Point subnode can be used to define the phase of the incident wave. This feature is showcased in the Refraction of Light Through an Optical Prism tutorial model.

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New and Updated Tutorial Models

COMSOL Multiphysics^® version 6.3 brings several new and updated tutorial models to the Wave Optics Module.

Dispersion and Hyperbolic Wave in a Metal–Dielectric Layered Metamaterial

An electric point dipole located in air near a metamaterial structure.

Instantaneous electric field magnitude excited in a hyperbolic metamaterial using an electric point dipole. The metamaterial is constructed using periodically organized metal–dielectric layers with subwavelength periodicity and thickness.

Application Library Title:
dipole_near_hyperbolic_metamaterial
Download from the Application Gallery

Refraction of Light Through an Optical Prism

A Gaussian beam with a right-angled triangular prism on top.

Refraction of a Gaussian beam in a right-angled triangular prism.

Application Library Title:
gaussian_beam_propagation_optical_prism
Download from the Application Gallery

SPP Excitation via Otto and Kretschmann Configuration

Two surface plasmon polariton models showing the SPP excitation.

Excitation of a surface plasmon polariton (SPP) in metal using Otto (left) and Kretschmann (right) configurations.

Application Library Title:
spp_otto_kretschmann
Download from the Application Gallery

Simulation of Dispersion and Surface Plasmon Polariton in Thin Metal Embedded in Dielectrics

A surface plasmon polariton model showing the electric field.

Electric field of an SPP propagating in a thin metal layer embedded in dielectrics.

Application Library Title:
thin_metal_surface_plasmon_polariton
Download from the Application Gallery

Waveguide with Scatterer

A 3D waveguide model showing the electric mode field near a metallic object.

Electric mode field norm in a dielectric slab waveguide with a lossy scatterer location near it.

Application Library Title:
waveguide_with_scatterer
Download from the Application Gallery

Acousto-Optic Modulator

A modulator model showing the mode fields.

The mode fields on the transmission side of the modulator. The central wave is the excitation mode, whereas the obliquely propagating waves are higher diffraction orders.

Application Library Title:
acousto_optic_modulator
Download from the Application Gallery

COMSOL Multiphysics® 6.3 Release Highlights