A method of trimming the refractive index of material forming at least part of one or more structures integrated in one or more pre-fabricated devices, the method comprising: implanting one or more first regions of material of one or more pre-fabricated devices, encompassing at least partially one or more device structures, with ions to alter the crystal form of the material within the one or more first regions and change the refractive index of the material within the one or more first regions; and heat treating one or more second regions of material of the one or more devices, encompassing at least partially the one or more first regions, to alter the crystal form of the material within the one or more first regions encompassed by the one or more second regions and change the refractive index thereof, thereby trimming the refractive index of the material of at least part of the one or more device structures, such that the one or more device structures provide one or more predetermined device outputs.

A photonic integrated circuit and a method of fabrication are provided which includes: a substrate; a first optical waveguide disposed, at least in part, extending across the substrate, the first optical waveguide being configured to transmit a first mode of light; and a second optical waveguide located at least partially over the first optical waveguide, the second optical waveguide being configured to transmit a second mode of light, wherein the first optical waveguide is vertically coupled to the second optical waveguide through a third optical waveguide disposed below the second waveguide.

A method of fabricating non-uniform gratings includes implanting different densities of ions into corresponding areas of a substrate, patterning, e.g., by lithography, a resist layer on the substrate, etching the substrate with the patterned resist layer, and then removing the resist layer from the substrate, leaving the substrate with at least one grating having non-uniform characteristics associated with the different densities of ions implanted in the areas. The method can further include using the substrate having the grating as a mold to fabricate a corresponding grating having corresponding non-uniform characteristics, e.g., by nanoimprint lithography.

A manufacturing method for an integrated structure of a waveguide and an active component is proposed. The manufacturing method includes providing a substrate including a dielectric layer and a semiconductor layer, and the semiconductor layer includes a waveguide region, a transition region and an active component region; etching the semiconductor layer to form a plurality of waveguide trenches; depositing a waveguide material on the semiconductor layer to form a deposition layer, and the waveguide trenches are filled with the waveguide material; performing an ion implantation process on the semiconductor layer to form a first doped portion and a second doped portion; etching the waveguide region, the transition region and the active component region to form a waveguide structure, a transition structure and an active component structure; depositing a cover layer on the dielectric layer; forming two via holes and two contact pads in the cover layer.

Described herein are stacked photonic integrated circuit (PIC) assemblies that include multiple layers of waveguides. The waveguides are formed of substantially monocrystalline materials, which cannot be repeatedly deposited. Layers of monocrystalline material are fabricated and repeatedly transferred onto the PIC structure using a layer transfer process, which involves bonding a monocrystalline material using a non-monocrystalline bonding material. Layers of isolation materials are also deposited or layer transferred onto the PIC assembly.

The present invention relates to a substrate comprising an ion-implanted layer, for example a cation, wherein the ion implanted layer has a uniform distribution of the implanted ions at a significantly greater depth than previously possible. The invention further comprises said substrate wherein the substrate is a silicon based substrate, such as glass. The invention also comprises the use of said material as a waveguide and the use of said material in measurement devices.

The present invention relates to a substrate comprising an ion-implanted layer, for example a cation, wherein the ion implanted layer has a uniform distribution of the implanted ions at a significantly greater depth than previously possible. The invention further comprises said substrate wherein the substrate is a silicon based substrate, such as glass. The invention also comprises the use of said material as a waveguide and the use of said material in measurement devices.

Described herein are stacked photonic integrated circuit (PIC) assemblies that include multiple layers of waveguides. The waveguides are formed of substantially monocrystalline materials, which cannot be repeatedly deposited. Layers of monocrystalline material are fabricated and repeatedly transferred onto the PIC structure using a layer transfer process, which involves bonding a monocrystalline material using a non-monocrystalline bonding material. Layers of isolation materials are also deposited or layer transferred onto the PIC assembly.

A semiconductor photonics device includes a multiple-layer coupler structure. The multiple-layer coupler structure includes a plurality of optical coupler layers, which enables the properties of the optical coupler layers to be configured to achieve efficient optical coupling for a broad spectrum of optical wavelengths. This enables the multiple-layer coupler structure to handle wide bandwidth optical signals, which enables the semiconductor photonics device to support high-bandwidth optical communication applications. Moreover, the optical coupler layers of the multiple-layer coupler device enable the performance of the multiple-layer coupler structure to be increased using less complex and less costly semiconductor manufacturing processes and techniques. Additionally, the optical coupler layers of the multiple-layer coupler structure enable the multiple-layer coupler structure to handle bidirectional transmission of optical signals, thereby enabling transmission of optical signals between various layers of the semiconductor photonics device.

A method of manufacturing a semiconductor photonic device includes: providing a first substrate comprising a base layer, an insulator layer overlying the base layer, and a surface layer overlying the insulator layer; forming an optical coupler in the surface layer of the first substrate; forming a temperature control member partially encircling the optical coupler; removing the base layer of the first substrate; and depositing a thermal preservation layer on the insulator layer of the first substrate, wherein the base layer of the first substrate has a first thermal conductivity and the thermal preservation layer has a second thermal conductivity less than the first thermal conductivity.