A rectangular optical waveguide, an optical phase shifter and an optical modulator each formed of a semiconductor layer are formed on an insulating film constituting an SOI wafer, and then a rear insulating film formed on a rear surface of the SOI wafer is removed. Moreover, a plurality of trenches each having a first depth from an upper surface of the insulating film are formed at a position not overlapping with the rectangular optical waveguide, the optical phase shifter and the optical modulator when seen in a plan view in the insulating film. As a result, since an electric charge can be easily released from the SOI wafer even when the SOI wafer is later mounted on the electrostatic chuck included in the semiconductor manufacturing apparatus, the electric charge is less likely to be accumulated on the rear surface of the SOI wafer.

There is set forth herein a method including building an interposer base structure on a first wafer having a first substrate, wherein the building an interposer base structure includes fabricating a plurality of through vias that extend through the first substrate and fabricating within an interposer base dielectric stack formed on the first substrate one or more metallization layer; building a photonics structure on a second wafer having a second substrate, wherein the building a photonics structure includes fabricating within a photonics device dielectric stack formed on the second substrate one or more photonics device; and bonding the photonics structure to the interposer base structure to define an interposer having the interposer base structure and one or more photonics device fabricated within the photonics device dielectric stack. There is set forth herein an optoelectrical system including a substrate; an interposer dielectric stack formed on the substrate, the interposer dielectric stack including a base interposer dielectric stack, and a photonics device dielectric stack, and a bond layer dielectric stack that integrally bonds the photonics device dielectric stack to the base interposer dielectric stack.

Some implementations described herein include a photonics integrated circuit device including a photonics structure. The photonics structure includes a waveguide structure and an optical attenuator structure. In some implementation, the optical attenuator structure is formed on an end region of the waveguide structure and includes a metal material or a doped material. In some implementations, the optical attenuator structure includes a gaussian doping profile within a portion of the waveguide structure. The optical attenuator structure may absorb electromagnetic waves at the end of the waveguide structure with an efficiency that is improved relative to a spiral optical attenuator structure or metal cap optical attenuator structure.

A semiconductor device includes an n-type ohmic contact layer, cathode and anode electrodes, p-type and n-type modulation doped quantum well (QW) structures, and first and second ion implant regions. The anode electrode is formed on the first ion implant region that contacts the p-type modulation doped QW structure and the cathode electrode is formed by patterning the first and second ion implant regions and the n-type ohmic contact layer. The semiconductor device is configured to operate as at least one of a diode laser and a diode detector. As the diode laser, the semiconductor device emits photons. As the diode detector, the semiconductor device receives an input optical light and generates a photocurrent.

Various embodiments of the present disclosure are directed towards a photonic device including a temperature adjustment element. A first waveguide overlies an insulating layer. A second waveguide overlies the insulating layer. The temperature adjustment element includes a heater structure aligned with a segment of the first waveguide and a cooler structure aligned with a segment of the second waveguide. The heater structure is configured to increase a temperature of the segment of the first waveguide to a first temperature. The cooler structure is configured to reduce a temperature of the segment of the second waveguide to a second temperature less than the first temperature.

Some implementations described herein include a photonics integrated circuit device including a photonics structure. The photonics structure includes a waveguide structure and an optical attenuator structure. In some implementation, the optical attenuator structure is formed on an end region of the waveguide structure and includes a metal material or a doped material. In some implementations, the optical attenuator structure includes a gaussian doping profile within a portion of the waveguide structure. The optical attenuator structure may absorb electromagnetic waves at the end of the waveguide structure with an efficiency that is improved relative to a spiral optical attenuator structure or metal cap optical attenuator structure.

An optical attenuator and/or optical terminator is provided. The device includes an optical channel having two regions with different optical properties, such as an undoped silicon region which is less optically absorptive and a doped silicon region which is more optically absorptive. Other materials may also be used. A facet at the interface between the two regions is oriented at a non-perpendicular angle relative to a longitudinal axis of the channel. The angle can be configured to mitigate back reflection. Multiple facets may be included between different pairs of regions. The device may further include curved and/or tapers to further facilitate attenuation and/or optical termination.

A method of making a photonic device includes depositing a cladding layer over a silicon layer. The method further includes patterning the cladding layer to expose a first portion of the silicon layer, wherein a second portion of the silicon layer is covered by the patterned cladding layer, and a waveguide portion is in the second portion of the silicon layer. The method further includes depositing a low refractive index layer directly over the patterned cladding layer, wherein a refractive index of the low refractive index layer is less than a refractive index of silicon nitride.

Provided is an optical waveguide circuit avoiding the difficulty of the property compensation based on temperature control, compensated with respect to the property variations due to fabrication error, particularly paid attention in a silicon waveguide, and being low in power consumption and high in performances. The optical waveguide circuit includes a silicon (Si) substrate, a buried oxide film (BOX) layer formed on the Si substrate, and an SOI (Silicon on Insulator) layer, formed on the BOX layer, including an optical element utilizing the SOI layer as a main optical transmission medium. At least part of a waveguide of the optical element includes uniformly distributed and thermally unstable crystal defects.

A semiconductor structure can include an active device FET region having a FET and a photonics region having a photonic device including a waveguide. A semiconductor structure can include an active device FET region having a FET and a trench isolation region having a photonic device that includes a waveguide. A method can include forming a FET at an active device FET region of a semiconductor structure. A method can include forming a photonic device at a trench isolation region of a semiconductor structure.