Abstract: A semiconductor arrangement and a method of forming the same are described. A semiconductor arrangement includes a first layer including a first optical transceiver and a second layer including a second optical transceiver. A first serializer/deserializer (SerDes) is connected to the first optical transceiver and a second SerDes is connected to the second optical transceiver. The SerDes converts parallel data input into serial data output including a clock signal that the first transceiver transmits to the second transceiver. The semiconductor arrangement has a lower area penalty than traditional intra-layer communication arrangements that do not use optics for alignment, and mitigates alignment issues associated with conventional techniques.

Abstract: An optical bench including a substrate having a trench with the trench having an angled sidewall on which a reflective coating is provided. The optical bench also includes a first device and a waveguide positioned within the trench, a second device optically connected to the first device, and at least one active circuit electrically connected to the first device with the waveguide being positioned optically between the first device and the reflective coating. The optical bench also includes an optically transparent material that forms a first interface with the first device and a second interface with a first surface of the waveguide.

Abstract: A method of making a grating in a waveguide includes forming a waveguide material over a substrate, the waveguide material having a thickness less than or equal to about 100 nanometers (nm). The method further includes forming a photoresist over the waveguide material and patterning the photoresist. The method further includes forming a first set of openings in the waveguide material through the patterned substrate and filling the first set of openings with a metal material.

Abstract: A method of forming a semiconductor package includes providing a substrate, wherein the substrate has at least one chip attached on an upper surface of the substrate. An insulating barrier layer is deposited above the substrate, wherein the at least one chip is at least partially embedded within the insulating barrier layer. A thermally conductive layer is formed over the insulating barrier layer to at least partially encapsulate the at least one chip.

Abstract: Some embodiments relate to a method of processing a workpiece. The workpiece includes a first surface region having a first wettability coefficient, and a second surface region having a second wettability coefficient that differs from the first wettability coefficient. A liquid, which corresponds to an optical structure, is dispensed on the first and second surface regions of the workpiece, wherein the liquid self-aligns to the second surface region due to the difference between the first and second wettability coefficients. The self-aligned liquid is hardened to form the optical structure.

Abstract: An optical bench includes a substrate having a trench therein, and a light emitting device within the trench. The optical bench further includes a light receiving device optically connected to the light emitting device. The optical bench further includes at least one active circuit electrically connected to the light emitting device. The optical bench further includes a waveguide in the trench, wherein the waveguide is optically between the light emitting device and the light receiving device. The optical bench further includes an optically transparent material between the light emitting device and the waveguide.

Abstract: An electro-optic modulator device includes a modulation region, a reflecting region, a conductive line and an anti-reflecting region. The modulation region includes a doped region. The reflecting region is over the modulation region. The conductive line is connected to the doped region. The conductive line extends through the reflecting region. The anti-reflecting region is on an opposite surface of the modulation region from the reflecting region.

Abstract: A method comprises forming a plateau region and a trench region over a substrate, wherein the trench region comprises a slope and a flat bottom, depositing a reflecting layer over the flat bottom and a portion of the slope, depositing a first adhesion promoter layer over the reflecting layer, applying a first curing process to the first adhesion promoter layer, wherein, after the first curing process finishes, the reflecting layer and the first adhesion promoter layer form a first bonding interface, depositing a bottom cladding layer deposited over the first adhesion promoter layer, applying a second curing process to the bottom cladding layer to form a second bonding interface layer, depositing a core layer over the bottom cladding layer and depositing a top cladding layer over the core layer.

Abstract: An apparatus and method of forming a chip package with a waveguide for light coupling is disclosed. The method includes depositing an adhesive layer over a carrier. The method further includes depositing a laser diode (LD) die having a laser emitting area onto the adhesive layer and depositing a molding compound layer over the LD die and the adhesive layer. The method still further includes curing the molding compound layer and partially removing the molding compound layer to expose the laser emitting area. The method also includes depositing a ridge waveguide structure adjacent to the laser emitting area and depositing an upper cladding layer over the ridge waveguide structure.

Abstract: A system and method of etching a semiconductor device are provided. Etching solution is sampled and analyzed by a monitoring unit to determine a concentration of components within the etching solution, such as an oxidant concentration. Then, based upon such measurement, a makeup amount of the components may be added be a makeup unit to the etching solution to control the concentration of the components within the etching system.

Abstract: A method of making a grating in a waveguide includes forming a waveguide material over a substrate, the waveguide material having a thickness less than or equal to about 100 nanometers (nm). The method further includes forming a photoresist over the waveguide material and patterning the photoresist. The method further includes forming a first set of openings in the waveguide material through the patterned substrate and filling the first set of openings with a metal material.

Abstract: A method of forming a semiconductor package includes providing a substrate, wherein the substrate has at least one chip attached on an upper surface of the substrate. An insulating barrier layer is deposited above the substrate, wherein the at least one chip is at least partially embedded within the insulating barrier layer. A thermally conductive layer is formed over the insulating barrier layer to at least partially encapsulate the at least one chip.

Abstract: A system and method for manufacturing semiconductor devices is provided. An embodiment comprises using an etchant to remove a portion of a substrate to form an opening with a 45° angle with a major surface of the substrate. The etchant comprises a base, a surfactant, and an oxidant. The oxidant may be hydrogen peroxide.

Abstract: Embodiments of forming a waveguide structure are provided. The waveguide structure includes a substrate, and the substrate has an interconnection region and a waveguide region. The waveguide structure also includes a trench formed in the substrate, and the trench has a sloping sidewall surface and a substantially flat bottom. The waveguide structure further includes a bottom cladding layer formed on the substrate, and the bottom cladding layer extends from the interconnection region to the waveguide region, and the bottom cladding layer acts as an insulating layer in the interconnection region. The waveguide structure further includes a metal layer formed on the bottom cladding layer on the sloping sidewall surface.

Abstract: An apparatus includes a package structure. The package structure includes a chip, a conductive structure over the chip, a molding structure surrounding and underneath the chip, and a first passivation layer over the conductive structure. The chip includes an optical component and a chip conductive pad. The conductive structure is electrically coupled to the chip conductive pad. The conductive structure has a planar portion substantially in parallel with an upper surface of the chip. The first passivation layer has a first opening defined therein. The first opening exposes a portion of the planar portion. The package structure is configured to receive an electrical coupling through the first opening in the first passivation layer.

Abstract: An approach is provided for aligning and leveling a chip package portion. The approach involves filling, at least partially, a reservoir formed between a first sidewall portion having a first slanted surface and a second sidewall portion having a second slanted surface with a fluid. The approach also involves placing a chip package portion into the reservoir. The approach further involves draining the fluid from the reservoir to cause the chip package portion to align with respect to a center of the reservoir. The chip package portion aligns with respect to the center of the reservoir and levels based on a relationship between the chip package portion, an angle of the first slanted surface, an angle of the second slanted surface, and the fluid. The chip package portion is secured in the aligned and leveled state by a molding compound.

Abstract: An electro-optic modulator device includes a modulation region, a reflecting region, a conductive line and an anti-reflecting region. The modulation region includes a doped region. The reflecting region is over the modulation region. The conductive line is connected to the doped region. The conductive line extends through the reflecting region. The anti-reflecting region is on an opposite surface of the modulation region from the reflecting region.

Abstract: A semiconductor device includes a first chip, a dielectric layer over the first chip, and a second chip over the dielectric layer. A conductive layer is embedded in the dielectric layer and is electrically coupled to the first chip and the second chip. The second chip includes an optical component. The first chip and the second chip are arranged on opposite sides of the dielectric layer in a thickness direction of the dielectric layer.

Abstract: A semiconductor arrangement and a method of forming the same are described. A semiconductor arrangement includes a first layer including a first optical transceiver and a second layer including a second optical transceiver. A first serializer/deserializer (SerDes) is connected to the first optical transceiver and a second SerDes is connected to the second optical transceiver. The SerDes converts parallel data input into serial data output including a clock signal that the first transceiver transmits to the second transceiver. The semiconductor arrangement has a lower area penalty than traditional intra-layer communication arrangements that do not use optics for alignment, and mitigates alignment issues associated with conventional techniques.

Abstract: A bio-chip package comprises a substrate a first layer over the substrate comprising an image sensor. The bio-chip package also comprises a second layer over the first layer. The second layer comprises a waveguide system a grating coupler. The bio-chip package also comprises a third layer arranged to accommodate a fluid between a first-third layer portion and a second-third layer portion, and to allow the fluid to pass from a first side of the third layer to a second side of the third layer. The third layer comprises a material having a predetermined transparency with respect to a wavelength of a received source light, the waveguide system is configured to direct the received source light to the grating coupler, and the image sensor is configured to determine a change in the wavelength of the source light caused by a coupling between the source light and the fluid.