Abstract: A method includes forming multiple photonic devices in a semiconductor wafer, forming a v-shaped groove in a first side of the semiconductor wafer, forming an opening extending through the semiconductor wafer, forming multiple conductive features within the opening, wherein the conductive features extend from the first side of the semiconductor wafer to a second side of the semiconductor wafer, forming a polymer material over the v-shaped groove, depositing a molding material within the opening, wherein the multiple conductive features are separated by the molding material, after depositing the molding material, removing the polymer material to expose the v-shaped groove, and placing an optical fiber within the v-shaped groove.

Abstract: A planarization method includes: providing a substrate, wherein the substrate includes a first region and a second region having different degrees of hydrophobicity or hydrophilicity, the second region covering an upper surface of the first region; polishing the substrate with a polishing slurry until the upper surface of the first region is exposed; and continuing polishing and performing a surface treatment by the polishing slurry to adjust the degree of hydrophobicity or hydrophilicity of at least one of the first region and the second region. The polishing slurry and the upper surface of the second region have a first contact angle, and the polishing slurry and the upper surface of the first region have a second contact angle. The surface treatment keeps a contact angle difference between the first contact angle and the second contact angle being equal to or less than 30 degrees during the polishing.

Abstract: A method includes forming multiple photonic devices in a semiconductor wafer, forming a v-shaped groove in a first side of the semiconductor wafer, forming an opening extending through the semiconductor wafer, forming multiple conductive features within the opening, wherein the conductive features extend from the first side of the semiconductor wafer to a second side of the semiconductor wafer, forming a polymer material over the v-shaped groove, depositing a molding material within the opening, wherein the multiple conductive features are separated by the molding material, after depositing the molding material, removing the polymer material to expose the v-shaped groove, and placing an optical fiber within the v-shaped groove.

Abstract: A slurry composition, a semiconductor structure and a method for forming a semiconductor structure are provided. The slurry composition includes a slurry and a precipitant dispensed in the slurry. The semiconductor structure comprises a blocking layer including at least one element of the precipitant. The method includes using the slurry composition with the precipitant to polish a conductive layer and causing the precipitant to flow into the gap.

Abstract: Semiconductor device includes light-emitting die and semiconductor package. Light emitting die includes substrate and first conductive pad. Substrate has emission region located at side surface. First conductive pad is located at bottom surface of substrate. Semiconductor package includes semiconductor-on-insulator substrate, interconnection structure, second conductive pad, and through semiconductor via. Semiconductor-on-insulator substrate has linear waveguide formed therein. Interconnection structure is disposed on semiconductor-on-insulator substrate. Edge coupler is embedded within interconnection structure and is connected to linear waveguide. Semiconductor-on-insulator substrate and interconnection structure include recess in which light-emitting die is disposed. Edge coupler is located close to sidewall of recess. Second conductive pad is located at bottom of recess. Through semiconductor via extends across semiconductor-on-insulator substrate to contact second conductive pad.

Abstract: A semiconductor package and a manufacturing method thereof are provided. The semiconductor package includes a photonic die, an encapsulant and a wave guide structure. The photonic die includes: a substrate, having a wave guide pattern formed at front surface; and a dielectric layer, covering the front surface of the substrate, and having an opening overlapped with an end portion of the wave guide pattern. The encapsulant laterally encapsulates the photonic die. The wave guide structure lies on the encapsulant and the photonic die, and extends into the opening of the dielectric layer, to be optically coupled to the wave guide pattern.

Abstract: Provided herein are chemical-mechanical planarization (CMP) systems and methods to reduce metal particle pollution on dressing disks and polishing pads. Such methods may include contacting a dressing disk and at least one conductive element with an electrolyte solution and applying direct current (DC) power to the dressing disk and the at least one conductive element.

Abstract: A method for forming a semiconductor device structure is provided. The method includes forming a first metal layer over a substrate, forming a dielectric layer over the first metal layer. The method includes forming a trench in the dielectric layer, and performing a surface treatment process on a sidewall surface of the trench to form a hydrophobic layer. The hydrophobic layer is formed on a sidewall surface of the dielectric layer. The method further includes depositing a metal material in the trench and over the hydrophobic layer to form a via structure.

Abstract: A LC lens and a liquid-crystal medium used in said LC lens, wherein the medium contains one or more compounds of each of formulae I and II

Abstract: A method includes forming multiple photonic devices in a semiconductor wafer, forming a v-shaped groove in a first side of the semiconductor wafer, forming an opening extending through the semiconductor wafer, forming multiple conductive features within the opening, wherein the conductive features extend from the first side of the semiconductor wafer to a second side of the semiconductor wafer, forming a polymer material over the v-shaped groove, depositing a molding material within the opening, wherein the multiple conductive features are separated by the molding material, after depositing the molding material, removing the polymer material to expose the v-shaped groove, and placing an optical fiber within the v-shaped groove.

Abstract: A semiconductor package and a manufacturing method thereof are provided. The semiconductor package includes a photonic die, an encapsulant and a wave guide structure. The photonic die includes: a substrate, having a wave guide pattern formed at front surface; and a dielectric layer, covering the front surface of the substrate, and having an opening overlapped with an end portion of the wave guide pattern. The encapsulant laterally encapsulates the photonic die. The wave guide structure lies on the encapsulant and the photonic die, and extends into the opening of the dielectric layer, to be optically coupled to the wave guide pattern.

Abstract: There is provided a system and method of performing a measurement with respect to an epitaxy formed in a finFET, the epitaxy being separated with at least one adjacent epitaxy by at least one HK fin. The method comprises obtaining an image of the epitaxy and the at least one HK fin, and a gray level (GL) profile indicative of GL distribution of the image; detecting edges of the at least one HK fin; determining two inflection points of the GL profile within an area of interest in the image; performing a critical dimension (CD) measurement between the two inflection points; determining whether to apply correction to the CD measurement based on a GL ratio indicative of a relative position between the epitaxy and the at least one HK fin; and applying correction to the CD measurement upon the GL ratio meeting a predetermined criterion.

Abstract: Provided herein are chemical-mechanical planarization (CMP) systems and methods to reduce metal particle pollution on dressing disks and polishing pads. Such methods may include contacting a dressing disk and at least one conductive element with an electrolyte solution and applying direct current (DC) power to the dressing disk and the at least one conductive element.

Abstract: There is provided a system and method of performing a measurement with respect to an epitaxy formed in a finFET, the epitaxy being separated with at least one adjacent epitaxy by at least one HK fin. The method comprises obtaining an image of the epitaxy and the at least one HK fin, and a gray level (GL) profile indicative of GL distribution of the image; detecting edges of the at least one HK fin; determining two inflection points of the GL profile within an area of interest in the image; performing a critical dimension (CD) measurement between the two inflection points; determining whether to apply correction to the CD measurement based on a GL ratio indicative of a relative position between the epitaxy and the at least one HK fin; and applying correction to the CD measurement upon the GL ratio meeting a predetermined criterion.

Abstract: A method for forming a semiconductor device structure is provided. The method includes forming a first metal layer over a substrate, forming a dielectric layer over the first metal layer. The method includes forming a trench in the dielectric layer, and performing a surface treatment process on a sidewall surface of the trench to form a hydrophobic layer. The hydrophobic layer is formed on a sidewall surface of the dielectric layer. The method further includes depositing a metal material in the trench and over the hydrophobic layer to form a via structure.

Abstract: A semiconductor package includes an interconnect structure, an insulating layer and a conductive layer. The interconnect structure includes a first surface and a second surface opposite to the first surface. The insulating layer contacts the interconnect structure. The insulating layer includes a third surface contacting the second surface of the interconnect structure and a fourth surface opposite to the third surface. The conductive layer is electrically coupled to the interconnect structure. The conductive layer has a continuous portion extending from the second surface to the fourth surface.

Abstract: A planarization method and a CMP method are provided. The planarization method includes providing a substrate with a first region and a second region having different degrees of hydrophobicity or hydrophilicity and performing a surface treatment to the first region to render the degrees of hydrophobicity or hydrophilicity in proximity to that of the second region. The CMP method includes providing a substrate with a first region and a second region; providing a polishing slurry on the substrate, wherein the polishing slurry and the surface of the first region have a first contact angle, and the polishing slurry and the surface of the first region have a second contact angle; modifying the surface of the first region to make a contact angle difference between the first contact angle and the second contact angle equal to or less than 30 degrees.

Abstract: A method includes forming multiple photonic devices in a semiconductor wafer, forming a v-shaped groove in a first side of the semiconductor wafer, forming an opening extending through the semiconductor wafer, forming multiple conductive features within the opening, wherein the conductive features extend from the first side of the semiconductor wafer to a second side of the semiconductor wafer, forming a polymer material over the v-shaped groove, depositing a molding material within the opening, wherein the multiple conductive features are separated by the molding material, after depositing the molding material, removing the polymer material to expose the v-shaped groove, and placing an optical fiber within the v-shaped groove.

Abstract: A semiconductor package includes an interconnect structure having a first surface and a second surface opposite to the first surface, an insulating layer contacting the second surface of the interconnect structure wherein the insulating layer has a third surface facing the second surface of the interconnect structure and a fourth surface opposite to the third surface, at least one optical chip over the fourth surface of the insulating layer and electrically coupled to the interconnect structure, and a molding compound over the first surface of the interconnect structure.

Abstract: A slurry composition, a polishing method and an integrated circuit are provided. The slurry composition includes a slurry and at least one cationic surfactant having at least one nitrogen atom in the molecule. The slurry includes at least one liquid carrier, at least one abrasive and at least one pH adjusting agent, and has a pH of less than 7.0. The polishing method includes using the slurry composition with the cationic surfactant to polish a conductive layer. The integrated circuit comprises a block layer comprising the cationic surfactant between a sidewall of the conductive plug and an interlayer dielectric layer.