A planar lightwave circuit structure based on a printed circuit board and its manufacturing method are provided. The manufacturing method includes: S1, preparing the printed circuit board; S2, adhering the lower cladding layer to one side of the printed circuit board, and then annealing process carried out; S3, jetting a lightwave circuit material on an upper surface of the lower cladding layer in a predetermined route through an electrohydrodynamic jet printing device to form lightwave circuit lines to be cured, the lightwave circuit material being a slurry containing silver ions and an ultraviolet (UV) curing agent; S4, curing the lightwave circuit lines through irradiation of UV light, the UV light irradiating onto the lightwave circuit lines through a lens assembly with slits; and S5, depositing an upper cladding layer on the lower cladding layer and the lightwave circuit lines, and then solidifying treatment carried out.

A metasurface optical device includes a substrate and a nano-structure layer. The nano-structure layer is arranged on the substrate and includes a plurality of photonic crystal units. Each photonic crystal unit includes a plurality of nano-structure units arranged on the substrate such that an energy bandgap is formed in a cross-section of the photonic crystal unit parallel to the substrate. The energy bandgap surrounds the center area of the cross-section.

An integrated circuit comprises: at least one photonic layer that includes one or more optical waveguides; a first optical coupler that couples at least a first optical mode outside of the photonic layer to a first waveguide in the photonic layer; a photonic device that includes one or more ports in the photonic layer; a first multi-port optical coupler that includes three or more ports in the photonic layer, including a first port optically coupled to the first optical coupler, a second port optically coupled to a first port of the photonic device, and a third port optically coupled to a first optical reflector configured to send substantially all optical power emitted from the third port of the first multi-port optical coupler back to the third port of the first multi-port optical coupler.

An integrated circuit comprises: at least one photonic layer that includes one or more optical waveguides; a first optical coupler that couples at least a first optical mode outside of the photonic layer to a first waveguide in the photonic layer; a photonic device that includes one or more ports in the photonic layer; a first multi-port optical coupler that includes three or more ports in the photonic layer, including a first port optically coupled to the first optical coupler, a second port optically coupled to a first port of the photonic device, and a third port optically coupled to a first optical reflector configured to send substantially all optical power emitted from the third port of the first multi-port optical coupler back to the third port of the first multi-port optical coupler.

The disclosed subject matter relates to semiconductor devices for use in optoelectronic/photonic applications and integrated circuit (IC) chips. More particularly, the present disclosure relates to photonic devices having thermally conductive layers for the removal of heat from optoelectronic components in the photonic devices.

One example LIDAR device comprises a substrate and a waveguide disposed on the substrate. A first section of the waveguide extends lengthwise on the substrate in a first direction. A second section of the waveguide extends lengthwise on the substrate in a second direction different than the first direction. A third section of the waveguide extends lengthwise on the substrate in a third direction different than the second direction. The second section extends lengthwise between the first section and the second section. The LIDAR device also comprises a light emitter configured to emit light. The waveguide is configured to guide the light inside the first section toward the second section, inside the second section toward the third section, and inside the third section away from the second section.

Structures including an optical component and methods of forming a structure including an optical component. The structure includes an optical component on a substrate, and a back-end-of-line stack including multiple metal levels. Each of the metal levels includes a dielectric layer and metal features positioned over the optical component as metal fill in the dielectric layer. The metal features in at least two of the metal levels are arranged to overlap such that the optical component is fully covered normal to the substrate.

Structures including an optical component and methods of forming a structure including an optical component. The structure includes an optical component on a substrate, and a back-end-of-line stack including multiple metal levels. Each of the metal levels includes a dielectric layer and metal features positioned over the optical component as metal fill in the dielectric layer. The metal features in at least two of the metal levels are arranged to overlap such that the optical component is fully covered normal to the substrate.

According to an example aspect of the present invention, there is provided an electro-optic plasmonic device comprising: a slot waveguide that is defined by a first metallic electrode, a second metallic electrode and dielectric material in a slot between the first and second metallic electrodes. The device is configured to utilize the electric field induced Pockels effect.

An optical circuit board of the present disclosure includes a wiring board and an optical waveguide located on the wiring board. The optical waveguide includes a lower cladding layer, a core located on the lower cladding layer, an upper cladding layer located on the lower cladding layer and covering the core, a first cavity extending from the upper cladding layer to the lower cladding layer and dividing the core, and at least two second cavities extending from the upper cladding layer to the lower cladding layer and located with the core therebetween in plan view. The first cavity has a first opening portion located on the upper cladding layer side and a first bottom portion located on the lower cladding layer side. The second cavities each include a second opening portion located on the upper cladding layer side and a second bottom portion located on the lower cladding layer side.