Abstract: A method for forming a via in a semiconductor device and a semiconductor device including the via are disclosed. In an embodiment, the method may include bonding a first terminal and a second terminal of a first substrate to a third terminal and a fourth terminal of a second substrate; separating the first substrate to form a first component device and a second component device; forming a gap fill material over the first component device, the second component device, and the second substrate; forming a conductive via extending from a top surface of the gap fill material to a fifth terminal of the second substrate; and forming a top terminal over a top surface of the first component device, the top terminal connecting the first component device to the fifth terminal of the second substrate through the conductive via.

Abstract: A method includes forming a plurality of dielectric layers over a semiconductor substrate, etching the plurality of dielectric layers and the semiconductor substrate to form an opening, depositing a first liner extending into the opening, and depositing a second liner over the first liner. The second liner extends into the opening. The method further includes filling a conductive material into the opening to form a through-via, and forming conductive features on opposing sides of the semiconductor substrate. The conductive features are electrically interconnected through the through-via.

Abstract: Embodiments provide a high aspect ratio via for coupling a top electrode of a vertically oriented component to the substrate, where the top electrode of the component is coupled to the via by a conductive bridge, and where the bottom electrode of the component is coupled to substrate. Some embodiments provide for mounting the component by a component wafer and separating the components while mounted to the substrate. Some embodiments provide for mounting individual components to the substrate.

Abstract: A semiconductor device includes a photonic die and an optical die. The photonic die includes a grating coupler and an optical device. The optical device is connected to the grating coupler to receive radiation of predetermined wavelength incident on the grating coupler. The optical die is disposed over the photonic die and includes a substrate with optical nanostructures. Positions and shapes of the optical nanostructures are such to perform an optical transformation on the incident radiation of predetermined wavelength when the incident radiation passes through an area of the substrate where the optical nanostructures are located. The optical nanostructures overlie the grating coupler so that the incident radiation of predetermined wavelength crosses the optical die where the optical nanostructures are located before reaching the grating coupler.

Abstract: Embodiments provide a high aspect ratio via for coupling a top electrode of a vertically oriented component to the substrate, where the top electrode of the component is coupled to the via by a conductive bridge, and where the bottom electrode of the component is coupled to substrate. Some embodiments provide for mounting the component by a component wafer and separating the components while mounted to the substrate. Some embodiments provide for mounting individual components to the substrate.

Abstract: Methods of singulation and bonding, as well as structures formed thereby, are disclosed. A method includes singulating a first chip and after the singulating the first chip, bonding the first chip to a second chip. The first chip includes a first semiconductor substrate and a first interconnect structure on a front side of the first semiconductor substrate. The singulating the first chip includes etching through a back side of the first semiconductor substrate through the first interconnect structure.

Abstract: A semiconductor device includes a photonic die and an optical die. The photonic die includes a grating coupler and an optical device. The optical device is connected to the grating coupler to receive radiation of predetermined wavelength incident on the grating coupler. The optical die is disposed over the photonic die and includes a substrate with optical nanostructures. Positions and shapes of the optical nanostructures are such to perform an optical transformation on the incident radiation of predetermined wavelength when the incident radiation passes through an area of the substrate where the optical nanostructures are located. The optical nanostructures overlie the grating coupler so that the incident radiation of predetermined wavelength crosses the optical die where the optical nanostructures are located before reaching the grating coupler.

Abstract: A method for forming a via in a semiconductor device and a semiconductor device including the via are disclosed. In an embodiment, the method may include bonding a first terminal and a second terminal of a first substrate to a third terminal and a fourth terminal of a second substrate; separating the first substrate to form a first component device and a second component device; forming a gap fill material over the first component device, the second component device, and the second substrate; forming a conductive via extending from a top surface of the gap fill material to a fifth terminal of the second substrate; and forming a top terminal over a top surface of the first component device, the top terminal connecting the first component device to the fifth terminal of the second substrate through the conductive via.

Abstract: In an embodiment, a device includes: a first wafer including a first substrate and a first interconnect structure, a sidewall of the first interconnect structure forming an obtuse angle with a sidewall of the first substrate; and a second wafer bonded to the first wafer, the second wafer including a second substrate and a second interconnect structure, the sidewall of the first substrate being laterally offset from a sidewall of the second substrate and a sidewall of the second interconnect structure.

Abstract: Methods of singulation and bonding, as well as structures formed thereby, are disclosed. A method includes singulating a first chip and after the singulating the first chip, bonding the first chip to a second chip. The first chip includes a first semiconductor substrate and a first interconnect structure on a front side of the first semiconductor substrate. The singulating the first chip includes etching through a back side of the first semiconductor substrate through the first interconnect structure.

Abstract: A method includes forming a plurality of dielectric layers over a semiconductor substrate, etching the plurality of dielectric layers and the semiconductor substrate to form an opening, depositing a first liner extending into the opening, and depositing a second liner over the first liner. The second liner extends into the opening. The method further includes filling a conductive material into the opening to form a through-via, and forming conductive features on opposing sides of the semiconductor substrate. The conductive features are electrically interconnected through the through-via.

Abstract: A semiconductor device includes a through-substrate via extending from a frontside to a backside of a semiconductor substrate. The through-substrate via includes a concave or a convex portion adjacent to the backside of the semiconductor substrate. An isolation film is formed on the backside of the semiconductor substrate. A conductive layer includes a first portion formed on the concave or convex portion of the through substrate via and a second portion formed on the isolation film. A passivation layer partially covers the conductive layer.

Abstract: A semiconductor structure and a manufacturing method thereof are provided. The semiconductor structure includes a semiconductor substrate, an interconnection structure, through substrate vias, conductive pillars and dummy conductive pillars. The interconnection structure is disposed at a front side of the semiconductor substrate, and comprises a stack of dielectric layers and interconnection elements spreading in the stack of dielectric layers. The through substrate vias separately penetrate through the semiconductor substrate and the stack of dielectric layers. The conductive pillars are disposed at a front side of the interconnection structure facing away from the semiconductor substrate, and respectively in electrical connection with one of the through substrate vias. The dummy conductive pillars are disposed aside the conductive pillars at the front side of the interconnection structure.

Abstract: In an embodiment, a device includes: a first wafer including a first substrate and a first interconnect structure, a sidewall of the first interconnect structure forming an obtuse angle with a sidewall of the first substrate; and a second wafer bonded to the first wafer, the second wafer including a second substrate and a second interconnect structure, the sidewall of the first substrate being laterally offset from a sidewall of the second substrate and a sidewall of the second interconnect structure.

Abstract: A semiconductor structure and a manufacturing method thereof are provided. The semiconductor structure includes a semiconductor substrate, an interconnection structure, a through substrate via, an insulating layer, a conductive pillar, a dummy conductive pillar, a passivation layer and a bonding pad. The interconnection structure is disposed over the semiconductor substrate. The through substrate via at least partially extends in the semiconductor substrate along a thickness direction of the semiconductor substrate, and electrically connects to the interconnection structure. The insulating layer is disposed over the interconnection structure. The conductive pillar is disposed in the insulating layer, and electrically connected to the through substrate via. The dummy conductive pillar is disposed in the insulating layer, and laterally separated from the conductive pillar. The passivation layer is disposed over the insulating layer.

Abstract: A semiconductor device includes a through-substrate via extending from a frontside to a backside of a semiconductor substrate. The through-substrate via includes a concave or a convex portion adjacent to the backside of the semiconductor substrate. An isolation film is formed on the backside of the semiconductor substrate. A conductive layer includes a first portion formed on the concave or convex portion of the through substrate via and a second portion formed on the isolation film. A passivation layer partially covers the conductive layer.

Abstract: Methods of singulation and bonding, as well as structures formed thereby, are disclosed. A method includes singulating a first chip and after the singulating the first chip, bonding the first chip to a second chip. The first chip includes a first semiconductor substrate and a first interconnect structure on a front side of the first semiconductor substrate. The singulating the first chip includes etching through a back side of the first semiconductor substrate through the first interconnect structure.

Abstract: An interconnect structure for an integrated circuit, such as a three dimensional integrated circuit (3DIC), and a method of forming the same is provided. An example interconnect structure includes a substrate, a through via extending through the substrate, and a liner disposed between the substrate and the through via. The substrate includes a tapered profile portion. The tapered profile portion abuts the liner.

Abstract: A semiconductor structure and a manufacturing method thereof are provided. The semiconductor structure includes a semiconductor substrate, an interconnection structure, a through substrate via, an insulating layer, a conductive pillar, a dummy conductive pillar, a passivation layer and a bonding pad. The interconnection structure is disposed over the semiconductor substrate. The through substrate via at least partially extends in the semiconductor substrate along a thickness direction of the semiconductor substrate, and electrically connects to the interconnection structure. The insulating layer is disposed over the interconnection structure. The conductive pillar is disposed in the insulating layer, and electrically connected to the through substrate via. The dummy conductive pillar is disposed in the insulating layer, and laterally separated from the conductive pillar. The passivation layer is disposed over the insulating layer.

Abstract: A device includes a first side interconnect structure over a first side of a substrate, wherein active circuits are in the substrate and adjacent to the first side of the substrate, a dielectric layer over a second side of the substrate, a pad embedded in the dielectric layer, the pad comprising an upper portion and a bottom portion formed of two different materials and a passivation layer over the dielectric layer.